Tag Archives: cognitive problems

Mental ill-health in MS: prevalence and causes

08/02/2026 Gavin Giovannoni

It is now well established that the burden of MS extends far beyond the purely neurological problems to include mental health.

Key points

Many patients with MS experience both anxiety and depression.
Other emotional and behavioural changes associated with MS include cognitive changes, apathy, inappropriate laughing and crying, euphoria, mania and bipolar disorder.
Physical symptoms like fatigue, sleep disturbances, concentration difficulties, numbness, tingling and dizziness may occur both in MS and in anxiety states, complicating diagnosis.
Unless severe anxiety symptoms are formally diagnosed as an anxiety disorder, individuals miss out on targeted treatments.
There is growing evidence that MS-related emotional changes are not necessarily a psychological consequence of living with a disability.
- They may have a biological origin related to structural damage in the brain, caused by the MS disease process.
- Brain imaging techniques that measure activity reveal how these brain networks function in real time.
Emotional changes sometimes occur as a side effect of medications used in the management of MS, including steroids used to treat MS relapses..

Background and introduction

Multiple sclerosis (MS) is a chronic, inflammatory and neurodegenerative disease of the central nervous system (CNS) that is typically defined by its physical manifestations, such as motor weakness, sensory disturbances and fatigue. However, the burden of MS extends far beyond the purely neurological problems to include cognitive changes and mental health disorders such as anxiety, depression, apathy, mania and uncontrolled laughter and crying.

Anxiety and depression in people with MS

Among the most prevalent mental health problems in MS is anxiety, a condition that for many years was overshadowed by the clinical and research focus on depression. Anxiety is not a secondary issue but a core component of the disease experience for many people with MS. Anxiety and depression in MS are closely related, with many patients experiencing both simultaneously. Indeed, the presence of depression in people with MS is a strong predictor of the future development of anxiety, and vice versa. Both conditions share common underlying psychological risk factors such as avoidant coping styles and low optimism as well as unhealthy behaviours like smoking or lack of exercise.

Many large-scale studies have shown that anxiety is more prevalent in the MS population than in the general population. Two meta-analyses published in 2017 and 2023 assessed more than 50 published studies; based on pooled results, they estimated that 22% and 36%, respectively, of people with MS experienced anxiety.^1,2 The prevalence rates for depressive disorders in people with MS are about 20−30%. Further research, utilising the UK MS Register, suggests that more than half (54%) of the 4000 patients recorded in the database have experienced clinically significant anxiety and 47% have experienced depression.³

The proportions of people with different levels of anxiety (normal, mild, moderate or severe) and who have a depression score of 8 or above (N = 1961). Data from UK MS Register.³

The proportions of people with different levels of depression (normal, mild, moderate or severe) and who have an anxiety score of 8 or above (N = 2268). Data from UK MS Register.³

By contrast, the lifetime prevalence of any anxiety disorder in the general population in the USA is around 29% (though the prevalence at a specific point in time is lower). Anxiety is also significantly more prevalent in MS than in many other chronic neurological conditions, suggesting a relationship that may be specific to the pathophysiology or lived experience of MS.

Psychiatric symptoms versus psychiatric disorders

A critical nuance in understanding the epidemiology of anxiety in MS lies in the distinction between clinically significant anxiety symptoms and formally diagnosed anxiety disorders. The two are related but not interchangeable, and the disparity between their prevalence rates reveals a crucial aspect of the clinical challenge. The 2017 meta-analysis that found a 22% prevalence for anxiety disorders also found a substantially higher (34%) prevalence of clinically significant anxiety symptoms.This discrepancy indicates that for every ten patients who meet the formal diagnostic criteria for a specific anxiety disorder, such as generalised anxiety disorder (GAD) or panic disorder, there are approximately 15 patients who experience a level of anxiety that is severe enough to cause distress and impair functioning but is not formally identified and diagnosed in a clinical setting. The result is that these individuals miss out on targeted interventions such as specific psychotherapies or drug treatment that they might otherwise receive.

This large population of symptomatic but undiagnosed individuals may exist for several reasons. First, there is considerable symptom overlap between anxiety and MS itself. Physical symptoms like fatigue, sleep disturbances, concentration difficulties, numbness, tingling and dizziness can be manifestations of either MS or an anxiety state, creating a diagnostic challenge for clinicians and confusion for people with MS. Second, both patients and clinicians may view anxiety as an ’understandable’ or ’normal’ psychological reaction to living with a chronic, unpredictable illness, rather than as a distinct, treatable clinical entity. Finally, the historical research emphasis on depression may have led to less routine screening for anxiety in clinical practice. As an MSologist, it is also essential to differentiate formal depressive disorders from clinically significant depressive symptoms, which are much commoner than disorders.

Among those who do meet the criteria for a formal disorder, GAD appears to be the most prevalent, followed by panic disorder and obsessive-compulsive disorder. Recognising the full spectrum of anxiety, from subclinical symptoms to formal disorders, is essential for developing effective screening protocols and ensuring that all people with MS experiencing anxiety receive appropriate care (see article on management of mental ill-health in MS).

Other emotional and behavioural changes

MS impairs neuropsychiatric function (the interplay between neurological and psychological functioning) in a similar manner to its effects on other neurological functions. Living with MS can result in personality changes and subsequent relationship problems.

Cognitive changes

Cognitive impairment (i.e. dysfunction), particularly slowed information processing speed, is a common, well-documented and debilitating feature of MS. Anxiety has a demonstrably detrimental effect on cognitive domains that are often already compromised in MS, such as attention and executive functions.

Apathy

Apathy, characterised by profound loss of interest, blunted affect and reduced motivation, is also common in MS, particularly advanced MS. It is often misdiagnosed as depression. Apathy is not merely a component of low mood but is linked to executive dysfunction. Predictors identified include depressive symptoms, poor global quality of life, and poor attention and information processing speeds, probably due to MS lesions in the frontal lobe.

Inappropriate laughing and crying

Pathological laughing and crying, also known as pseudobulbar affect (PBA), are common but under-recognised and undertreated symptoms of MS that can be highly distressing and embarrassing for the patient and their relatives. The sudden, involuntary and explosive expressions of laughter or crying characteristic of PBA are often disproportionate or unrelated to the individual’s underlying emotional state.PBA is also associated with cognitive and mood problems, though the sudden and disproportionate emotional reactivity differentiates it from depression. The clinical presentation is due to frontal lobe or brainstem damage resulting from MS, which disrupts motor control pathways for emotional expression.

Rare affective changes

Euphoria and mania are relatively uncommon in people with MS but are often triggered by high-dose steroids used to treat MS relapses.

Bipolar disorder is significantly more common in people with MS than in the general population; please see the separate post/chapter on this. The diagnosis must be made and treated by psychiatrists and involves lifelong therapy.

The biological basis of mental illness in MS

MS-related emotional and mood changes are not necessarily a consequence of disability; they are often intrinsic to the MS disease process. This was recognised by the French neurologist Charcot, who, in 1877, noted pathological laughing, weeping, euphoria and depression in his patients who had MS.

Anxiety as a manifestation of MS pathology

While the psychological stress of living with a chronic illness contributes to anxiety in MS, there is growing evidence that anxiety is not solely a reactive or psychological phenomenon. The same autoimmune attack that damages myelin and axons, leading to physical disability, also targets and disrupts the complex neural circuits responsible for mood regulation, threat perception and emotional processing.

Neuroinflammation and demyelination (damage to nerve insulation) are directly implicated in the development of anxiety and other psychiatric disorders. MS lesions are not confined to areas of the brain responsible for motor and sensory function but also occur within the networks that govern emotion and mood.

Structural and functional brain changes

Research has shown that people with MS can develop gradual grey matter loss in brain regions involved in emotion and motivation, particularly the limbic system and the basal ganglia. The limbic system includes the hippocampus, amygdala and cingulate cortex, and it plays a central role in processing emotions. Changes in the shape of the hippocampus have also been observed.

Primary components of the limbic system. Modified from Encyclopaedia Britannica Inc.

These structural changes are thought to contribute to the development of mood and anxiety problems in MS. When MS-related inflammation, demyelination (damage to nerve insulation) or atrophy affects these areas, the brain’s ability to regulate fear and emotional responses can be disrupted. This creates a biological vulnerability to anxiety. From a structural perspective, therefore, anxiety in MS can be viewed as a direct consequence of neurological damage, in the same way that damage to the optic nerve causes visual impairment, or damage to the spinal cord leads to motor weakness.

In people with MS, depressive symptoms are consistently correlated with the volume of lesions in the brain and the degree of damage to connections between the cortex and subcortex. Neuroimaging studies show an association between depression and damage in the frontal and temporal areas of the cortex. In contrast, PBA is associated with lesions in the brainstem.

Brain imaging techniques that measure activity, such as functional MRI (fMRI), help to explain how these structural changes translate into anxiety symptoms. Rather than only showing where structural damage exists, fMRI studies reveal how brain networks function in real time. One key process identified in anxious people with MS is ‘fear overgeneralisation’. This occurs when the brain reacts to safe or neutral situations as if they were dangerous. For example, an individual learns to associate a specific signal (e.g. a picture of a circle) with a negative outcome (e.g. a mild electric shock). Anxious individuals tend to ’overgeneralise’ this fear, responding with fear to a similar but harmless signal (e.g. an oval), thus expanding their perception of danger in everyday life.

fMRI studies show that this process mainly involves the hippocampus (which is responsible for comparing incoming new experiences with ‘learned’ memories of danger) and the anterior insula (which plays a key role in generating the physical and emotional feeling of fear). In MS patients with anxiety, the physical pathways connecting these two regions are often disrupted, so that accurate information from the hippocampus is less effectively communicated to the anterior insula. As a result, the anterior insula may generate strong fear responses even when a situation is only mildly threatening or even safe.

fMRI studies have also revealed that many MS patients exhibit greater brain responses or increased recruitment of key emotional regions (e.g. prefrontal cortex and amygdala) compared to healthy controls. This likely reflects compensatory mechanisms the brain deploys to limit the clinical expression of emotional symptoms. The damaged MS brain tries to cope.

Neurological versus psychological causes

MS can trigger primary psychopathology as a result of demyelination and damage to specific functional circuits within the brain, as described above.It can be challenging to differentiate primary organic issues from reactive psychological problems, which is why people with MS may be referred for psychiatric assessments.

I have, however, also seen patients in whom the initial symptoms were psychiatric, e.g. depression or (rarely) mania, but who were later found to have MS. The link between MS-related CNS damage and emotional symptoms is based on lesion location and lesion burden. For example, MS patients with lesions affecting the functional parts of the brain (rather than the connecting structures) exhibit a higher burden of emotional symptoms than those with lesions confined to the spinal cord. Our emotions are part of brain function in a similar way to motor function. Therefore, it is not surprising that MS impacts emotions.

Lesion location and emotional symptoms

The evidence for a direct correlation between lesion location and anxiety is inconsistent. Some researchers suggest that, unlike depression, anxiety in MS may be driven more by psychosocial pressures and the psychological reaction to the illness rather than by focal brain damage.This discrepancy does not necessarily invalidate the biological basis of anxiety in MS. It may be that anxiety is related to more diffuse or subtle pathological changes, such as microstructural damage in white matter tracts or widespread neuroinflammation, that are not easily captured by conventional MRI lesion analysis. It is also possible that the broad distribution of the brain’s anxiety circuits means that damage to any number of different locations could produce a similar clinical outcome, making it difficult to pinpoint a single ’anxiety-causing’ lesion location.

Other contributing factors

Emotional changes may occur as a side effect of medications used in the management of MS, including certain disease-modifying therapies. People with MS are also susceptible to the effects of the menopause, seasonal affective disorder and comorbidities associated with depression and anxiety, such as alcohol and other substance misuse disorders. It is advisable, therefore, to have a complete assessment before having a mood disorder labelled as being due to MS.

Anxiety in MS may also be caused by high-dose corticosteroids, which are the standard treatment for MS relapses. Steroids have significant neuropsychiatric side effects, including anxiety, mania, insomnia and psychosis.For someone with MS already dealing with the stress of a relapse, the addition of steroid-induced anxiety can be particularly distressing.

‘Prodromal’ MS and psychiatric symptoms

Psychiatric comorbidities, such as anxiety and depression, have historically been viewed as consequences that follow the diagnosis of MS. Recent research, however, points to the existence of an ‘MS prodrome’, during which anxiety and depression occur years before the first classical neurological event.⁴ Increased rates of anxiety are a significant feature of this prodromal phase, suggesting that anxiety and/or depression may be early signs of MS, not merely a consequence. This body of recent research supports the idea that psychiatric symptoms in MS have a biological origin. This is most likely driven by the same low-level, diffuse neuroinflammatory and neurodegenerative processes that are smouldering away in the CNS long before the first eloquent MS lesion.

References

Boeschoten, RE et al. Prevalence of depression and anxiety in multiple sclerosis: A systematic review and meta-analysis. J Neurol Sci 2017;372:331−341.
Zhang X et al. The prevalence and risk factors of anxiety in multiple sclerosis: A systematic review and meta-analysis. Front Neurosci 2023;17:1120541.
Jones KH, et al. A large-scale study of anxiety and depression in people with multiple sclerosis: a survey via the web portal of the UK MS Register. PLoS ONE 2012;7:e41910.
Ruiz-Algueró, M et al. Health care use before multiple sclerosis symptom onset. JAMA Netw Open 2025;8:e2524635.

Bladder and bowel, Intimate issues

Intimate issues: bladder dysfunction

21/07/2025 Gavin Giovannoni

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.

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.
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.
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.
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.
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.
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.
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

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.
Kaninia S, et al. Dehydration associates with lower urinary tract symptoms in progressive multiple sclerosis. Eur J Neurol 2024;31: e16175.