Abstract

Multiple sclerosis (MS) is an uncommon neurological pathology frequently initially discovered by primary care providers in their workup of new focal neurological deficits. Many cases go undiagnosed for years despite multiple flares, with risk of cumulative disability. Early treatment is key to slowing or preventing the accumulation of this disability and maximizing function in the long term. This literature review covers all aspects of MS, including pathophysiology, diagnostic testing and differential diagnosis, disease classification, and disease-modifying agents for acute and chronic treatment. This study also summarizes support services, including osteopathic manipulative treatment, that help to maximize patient function and independence. While better therapeutics continue to emerge, significant limitations, side effects and continued progression—despite optimal therapy—result in progressive and irreversible loss of function for many patients. Heightened awareness of current progress in MS diagnosis criteria and initial testing amongst primary care providers can shorten the time to treatment and formal diagnosis, allowing patients to live their best lives despite their MS diagnosis.


Corresponding Author(s)

Ethan Charles Blocher-Smith, MS, DO eblochersmith756@marian.edu

The authors received no financial support related to this submission and have no financial affiliations or conflict of interest related to this article to disclose.

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INTRODUCTION

Multiple sclerosis (MS) is a complex disease state in which autoantibodies attack the central nervous system (CNS). These attacks result in progressive damage and subsequent disability, with eventual discovery typically coming from this disability. MS has an estimated minimum prevalence of 2.88 per 1000 individuals in the United States and, like most autoimmune conditions, is more likely in women with ~3:1 predominance.1 The exact cause of this immune attack is unknown and appears to be multifactorial. There does appear to be a genetic component, as studies have shown a correlation between risk of MS in families proportional to amount of genetic similarity.2 A monozygotic twin carries a risk of 25% for MS if their twin has the disease, which drops to around 5% for dizygotic twins or primary relatives, 1-2 percent for secondary relatives, and above base rate but less than 1% for tertiary relatives.2 However, the low rates of incidence even with identical DNA imply a concomitant environmental component. Cases have been reported after Epstein–Barr virus,3 human herpesvirus 64 and mycoplasma pneumoniae exposures,5 implying a possible mechanism similar to that in type 1 diabetes with Coxsackie B virus,6 with structures similar to that of the myelin sheath presenting on these agents to the immune system. Low vitamin D levels are shown to increase risk of MS,7 with possible mechanism via immune cell activation on B/T cells and macrophages by vitamin D receptors.8 This does also result in significant difference in MS prevalence based on latitude of primary residence. While several studies have argued that increased Vitamin D supplementation may modify MS severity, this is not conclusively proven with substantial disagreement in the literature at this time.7 Smoking also appears to contribute, with history of smoking associated with relative risk of 1.5 for MS diagnosis, along with worsening frequency of relapse, higher conversion to progressive MS from remitting courses, and increased rate of disability accumulation.9 There does appear to be an association with obesity as well, with a recent pediatric study showing twice the rate of MS in obese German children (OR 2.19 females, 2.14 males, p≤0.003) and worse response to first line agents in obese children, though whether this is causative or simply a secondary association is unknown.10

PATHOPHYSIOLOGY

While the initial cause of autoimmune attack is multifactorial and still not fully understood, the mechanism of injury and progression of an MS flare are well characterized. Classically, it was thought that CD4+ T-cells caused the injury in MS.11 Further characterization has shown involvement of much of the immune system, with CD8+ T-cells, B-cells, Th1 and Th17 helper cells, CD4 and CD8+ T-regulatory cells, NK cells, mast cells, dendritic and microglial cells, macrophages, among others.12,13,14 These immune cells infiltrate a region within the CNS and attack nearby myelin sheaths and their supporting oligodendrocytes.15 Depending on the severity of attack, this may only demyelinate a number of neurons resulting in temporary loss of their function until this sheath repairs itself across a period of weeks to months. In more severe episodes, however, this may progress to neuronal death, resulting in permanent loss of function.15 As this attack increases in severity, the more temporary and permanent disability will occur with each episode. This accumulation of immune cells, damaged neurons, and surrounding inflammatory edema/cytokines results in characteristic plaques that are easily seen on MRI.16 As the inflammation clears, glial cells proliferate to fill in any residual defect resulting in astrogliosis, leaving a permanent “scar” of the neural tissue.16

TABLE 1:

EDSS Scale. The scale uses assessment in 8 functional systems (FS): Cognition and memory, pyramidal, sensory, visual, bowel/ bladder function, cerebellar, brainstem, and other. A score of 4 or less is still fully ambulatory, with rapid loss of function at higher scores. In most studies, worsening disability is defined as a persistent increase in EDSS of 1 point or more.19 

SCORE

DESCRIPTION

0

Normal neurological exam, no disability in any FS.

1.0

No disability, minimal signs in 1 FS.

1.5

No disability, minimal signs in >1 FS.

2.0

Minimal disability in 1 FS.

2.5

Mild disability in 1 FS or minimal disability in 2 FS.

3.0

Moderate disability in 1 FS, or mild disability in 3-4 FS. No impairment to walking.

3.5

Moderate disability in 1 FS and more than minimal disability in several others. No impairment to walking.

4.0

Significant disability but self-sufficient and mobile

≥12 hours a day. Able to walk without aid or rest for 500 m.

4.5

Significant disability but up and about much of the day, able to work a full day, may otherwise have some limitation of full activity or require minimal assistance. Able to walk without aid or rest for 300 m.

5.0

Disability severe enough to impair full daily activi- ties and ability to work a full day without special provisions. Able to walk without aid or rest for 200 m.

5.5

Disability severe enough to preclude full daily activities. Able to walk without aid or rest for 100 m.

6.0

Requires a walking aid to walk about 100 m with or without resting.

6.5

Requires two walking aids to walk about 20 m without resting.

7.0

Unable to walk beyond ~5 m even with aid. Essentially restricted to wheelchair, wheeling self in standard wheelchair and transfers alone. Up and about in wheelchair ≥12 hours a day.

7.5

Unable to take more than a few steps. Restricted to wheelchair and may need aid in transferring. Can wheel self but cannot complete full day in standard and may require motorized wheelchair.

8.0

Essentially restricted to bed or chair or pushed in wheelchair. May be out of bed itself much of the day. Retains many self-care functions. Generally, has effective use of arms.

8.5

Essentially restricted to bed much of day. Has some effective use of arms retains some self-care functions.

9.0

Confined to bed. Can still communicate and eat.

9.5

Confined to bed and totally dependent. Unable to communicate effectively or eat/swallow.

10.0

Death due to MS.

The exact loss of function resulting from a MS flare is dependent on the location of the immune attack. Occipital or medullary lesions may cause blindness or ophthalmoplegia, cerebellar lesions may cause poor balance, damage to the motor cortex or motor pathways in the spinal cord may cause paralysis, damage to frontal territories may affect behavior or mood, etc.17 Due to the fact that every neurological system may be affected, initial diagnosis of MS may be very challenging. This is especially concerning, as every new attack without medication support is a roll of the dice to permanently lose CNS function.18 Disability in MS is typically scored by the Kurtzke Expanded Disability Status Scale (EDSS) a scale that ranges from 0–10 as shown in Table 1.19 Prior to the creation of modern therapies for treatment, mean progression of disability was estimated at 0.27 EDSS points every 2 years for patients with relapsing-remitting MS.20 More recent studies have shown >50% of progressive MS cases will have EDSS >6 within 10 years of symptom onset.21 Additionally, many patients may not realize the significance of early deficits, instead thinking that they are simply being clumsy or mistaking mood changes as a primarily psychological issue instead of the true neurological cause. As such, many primary care physicians (PCPs) may treat patients conservatively for an extended period before recognizing the significance of these disparate symptoms. A 2018 Swiss review of 1059 patients found only 62.7% of their patients were diagnosed within 2 years from initial symptoms, despite 90% having seen their PCP within the year prior to diagnosis.22 Items from this study associated with a longer time to diagnoses were male sex, a general practitioner as the first provider contacted, and atypical symptoms from first episode.22 Symptoms that are most common are those associated with the largest brain volume, since lesions may appear anywhere in the CNS. Thus, vision, balance, emotional and motor disturbances are most common, with hearing, speech, dysphagia, respiratory issues, or seizures less likely but still possible.23 Aggressively treating to limit the level of immune destruction with intervention as soon as possible after diagnosis will reduce the rate of disability in both the short and long term.

DIAGNOSIS

The hallmark of MS is lesions disseminated in both space and time—first identified in 1965 by the panel of multiple sclerosis24— with diagnosis now most commonly occurring under the McDonald Criteria. Originally developed in 2001 by Professor Ian McDonald of London University, a New Zealand neurologist and the foremost expert of his time on MS, along with a team of experts, these guidelines are the standby for rigorous clinical diagnosis.25 The most recent revision, published in 2017, focuses on diagnosis as early as possible while still meeting guidelines to prevent misdiagnosis.26

The standby of diagnosis is magnetic resonance imaging (MRI) evidence of lesions characteristic of MS, with 2 clinical attacks and evidence of 2 different lesions categorically defining MS.25 However, these recent changes now allow detection of CSF specific oligoclonal bands to substitute for dissemination in time requirement, allowing diagnosis of MS with a single attack so long as at least 2 lesions are characterized at that time.26 As previously mentioned, some patients may not have recognized a prior flare and its sequelae, allowing earlier diagnosis and treatment. Typical studies for a high index of suspicion for MS include MRI of the brain and/or spinal cord, CSF analysis with paired serum sample for oligoclonal band analysis, and evoked potential studies.23 Early referral to neurology for assessment is also extremely important. These will now each be reviewed in detail.

MRI studies of the brain and spinal cord are ordered, as comprehensive evaluation of the CNS is appropriate to characterize all lesions for diagnosis. Additionally, use of gadolinium enhancement contrast can allow for differentiation of acute lesions with high uptake vs chronic lesions with gliosis scarring. Lesions are classified into 4 regions: periventricular, cortical/juxtacortical, infratentorial and spinal cord.27 CSF analysis will show high protein secondary to albuminocytological dissociation. This finding, classically associated with Guillain-Barré syndrome, is positive in any CNS demyelinating process as the excess protein without cellular content is from the fragments of myelin sheath that have been destroyed.28 Additionally, CSF specific oligoclonal bands, seen only in the CSF and not in the paired serum sample drawn concurrently, correspond to the IgG antibodies attacking the brain. In particularly severe cases, there may also be IgM antibodies that are CSF specific. This corresponds to much worse outcomes overall.29 Evoked potential studies look at systems that are challenging to examine precisely and have a high risk of clinically occult deficits. This includes visual testing, auditory testing, brainstem evoking potentials, and somatosensory testing. For example, testing of vision involves use of visual stimulus with measured conductivity of the optic nerve pathway. This is an extremely sensitive test with any change to the nerve pathway resulting in measurable signal variance.30 Lastly, autoantibody testing may come into play for differentiating alternative diagnoses in an atypical presentation for MS and would exclusively be ordered by a neurologist.

Disease classification

Multiple sclerosis may present as 1 of 4 categories of disease state (see Figure 1):

  1. Clinically Isolated Syndrome (CIS): This person has symptoms of MS lasting at least 24 hours but has not yet been formally diagnosed with a true MS diagnosis. This gateway diagnosis is placed on any individual who does not yet clearly meet both the dissemination in space and dissemination in time requirements for MS. Many people may never show a second episode and thus never qualify as MS. Many are properly differentially diagnosed with alternative conditions, such as optic neuritis, that have similar symptoms. However, individuals considered at high risk of progression to a formal MS diagnosis may receive disease-modifying drugs with full U.S. Food and Drug Administration (FDA) approval.31

  2. Relapsing Remitting Multiple Sclerosis (RRMS): This is the most common type of MS encompassing about 85% of patients with true MS diagnosis. This patient will have periodic episodes of MS flares, with partial to full recovery to prior baseline after each episode. They do not tend to worsen outside of individual flares, though each flare carries the risk of more persistent deficits and progressive debility and disability as more damage accumulates in the CNS.31

  3. Secondary Progressive Multiple Sclerosis (SPMS): This type of MS initially presents as RRMS but then worsens, with slow progressions of disability both with and without evidence of acute flares. While singular severe flares certainly still occur, the majority of disability and loss of function occurs as a slow worsening outside of these flares.31

  4. Primary Progressive Multiple Sclerosis (PPMS): This is the worst type of MS with rapid progression of disability. There is no respite period of RRMS initially, instead demonstrating the same constant accumulation of disability seen in SPMS. As with SPMS, this accumulation may happen independently of visualized new activity/lesions on MRI.31

Remember that just because a new lesion appears and there is new damage, the patient may not show symptoms. Similarly, new deficits may appear without new lesions due to worsening damage in existing territories.31


FIGURE 1:

Illustration of disease course for MS diagnoses.

This article was originally published as a PDF. Please download the PDF for best viewing of the tables and figures. 

FIGURE 1A:

CIS, in this case with persistent disability.

This article was originally published as a PDF. Please download the PDF for best viewing of the tables and figures. 

FIGURE 1B:

RRMS. Note return to baseline for flares 1 and 4, with disability progression for flares 2 and 3.

This article was originally published as a PDF. Please download the PDF for best viewing of the tables and figures. 

FIGURE 1C:

SPMS. Note RRMS final peak followed by start of constant disability accumulation. Once SPMS starts, in between flares is only ever worsening or flat.

This article was originally published as a PDF. Please download the PDF for best viewing of the tables and figures. 

FIGURE 1D:

PPMS, which starts immediately with constant progression and rapid deterioration.

This article was originally published as a PDF. Please download the PDF for best viewing of the tables and figures. 

Differential diagnoses

As would be expected in a condition with such a wide range of symptoms, the list of potential alternative diagnoses is extensive. Many other conditions may cause MRI enhancing lesions with acute deficits, such as tertiary syphilis, human immunodeficiency virus, human T-lymphotropic virus type 1 or Lyme disease.32,33 Many alternative autoimmune conditions may also mimic this, such as sarcoidosis, lupus of the CNS, Sjögren’s syndrome, Behçet’s disease or vasculitis of the CNS.32,34,35 Rarer inflammatory conditions—such as neuromyelitis optica spectrum disorder, acute disseminated encephalomyelitis or myelin oligodendrocyte glycoprotein-related demyelination—are also possible but outside the scope of this review. Nutritional deficits can mimic the neuropathy and myelopathy symptoms of MS, such as B12 and copper deficiency.32,36,37 Lastly, sudden onset deficits should always raise concern for primary vascular cause, such as primary stroke, as well as rare diagnoses, including cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL), which causes recurrent strokes with white matter lesions or retinocochleocerebral vasculopathy (Susac syndrome), which may cause sudden onset speech and hearing deficits.32,38,39 Well-characterized MRI early in the disease course is most essential for effective differential diagnosis of these conditions. Nearly every case of MS will start showing symptoms between the ages of 20 and 50, with a vanishingly small number of cases in patients younger than 10 years old and 3.4% first diagnosed after 50.1,40 However, due to the quality of new treatments and improved survivability, recent evaluations have shown peak prevalence in the 55–65 age group.1

TREATMENT

The top goals in multiple sclerosis are reducing number of flares, reducing severity of flares when they happen, and limiting persistent disability. These will each be discussed in turn. Nearly all medications that decrease frequency of flares also reduce severity, though some medications are used only for acute treatment of a new flare rather than for general prevention.41

TABLE 2:

Medications for MS management. Many additional medication trials exist, but only included those currently in phase 3 trials are included here. Many new medications seek to attack the Bruton’s tyrosine kinase to reduce B-cells; however, no medication with this mechanism is currently FDA approved.


CLASS

GENERIC

BRAND

ROUTE

RRMS

SPMS

PPMS

2ND LINE


Sphingosine-1 Phosphate Receptor

Fingolimod

Gilenya®

Oral

X

X



Ozanimod

Zeposia®

Oral

X

X



Ponesimod

Ponvory®

Oral

X

X



Siponimod

Mayzent®

Oral

X

X




Fumarate

Dimethyl Fumarate

Tecfidera®

Oral

X

X



Diroximel Fuma- rate

Vumerity®

Oral

X

X



Monomethyl Fumarate

Bafiertam®

Oral

X

X



Dihydroorotate Dehydrogenase

Teriflunomide

Aubagio®

Oral

X

X



Adenosine Analogue

Cladribine

Mavenclad®

Oral

X

X


X


Interferon Modulators

Interferon ß-1a

Avonex®

Injection

X

X



Rebif®

Injection

X

X



Peginterferon ß-1a

Plegridy®

Injection

X

X



Interferon ß-1b

Betaseron®

Injection

X

X



Extavia®

Injection

X

X




Myelin Protein Inducers

Glatirimer Acetate

Copaxone®

Injection

X

X



Glatirimer Acetate

Glatopa®

Injection

X

X




CD20

Targeting

Ofatumumab

Kesimpta®

Injection

X

X

X


Ocrelizumab

Ocrevus®

Injection

X

X



Ublituximab (Phase 3)

TG-1101

Oral

X




CD52

Targeting

Alemtuzumab

Lemtrada®

Infusion

X

X


X

α4 Integrin Targeting

Natalizumab

Tysabri®

Infusion

X

X



Antineoplastic DNA

Crosslinking


Mitoxantrone


Novantrone®


Infusion


X


X




Other

Evobrutinib (Phase 3)

M-2591

Oral

X




Tolebrutanib (Phase 3)

PRN-2246

Oral

X




Fenebrutanib (Phase 3)

RG-7845

Oral

X





Direct immune modulation takes the form of oral, injectable, and infusion medications, as illustrated in Table 2. Medications targeting the sphingosine-1 phosphate receptors (-imod) work to decrease lymphocyte entry into the CNS by sequestration in the lymph nodes, thus reducing risk of damage.42 Fumarate compounds are poorly understood but appear to modulate severity of inflammation from immune responses via antioxidative effect and are also commonly used in treatment of other inflammatory conditions like psoriasis.43 Teriflunomide, similar to the agent leflunomide in rheumatoid arthritis, inhibits the DHO- DH enzyme resulting in impaired B- and T-cell production and suppressing immune response.44 Cladribine is an adenosine analogue that is cytotoxic in its triphosphorylated form, though it only achieves this active form in cell lines that have low 5’-nucleotidase activity, such as lymphocytes, resulting in differential apoptosis of these immune cells.45 However, cladribine is not perfectly targeted and thus has high risk of side effects due to cell death in other cell lines, making it a second line agent.45

Next, most injectable products focus on immune modulation via interferon beta. IFNß-1a is naturally produced in the human body, while IFNß-1b is a recombinant form of IFNß produced in E. coli. While the exact mechanism is not fully understood, IFNß reduces T-cell activity with emphasis on Th17, reduces pro-inflammatory cytokines and decreases lymphocyte entry into the CNS.46 Alternatively, glatiramer acetate induces excess production of myelin sheath proteins, reducing damage to the actual myelin sheaths, while modulating immune response.47

Lastly, a number of monoclonal antibody products exist, all of which focus on destruction of lymphocytes. Several agents target CD20 which is expressed on B-cells resulting in focal destruction.48 Another attacks CD52, an antigen present on most immune cells including B-/T-/NK-cells, monocytes, and macrophages.49 Yet another attacks the α4 subunit of integrins, binding it and thus blocking the crossing of leukocytes through the blood-brain barrier.50 Lastly, mitoxanantrone, an analogue of doxorubicin, directly attacks the cells via DNA crosslinking with strand breakage, destroying cell replication in immune cells and thus reducing them.51 As with cladribine, this does result in some damage to other cells lines, resulting in this classification as a second line agent. Efficacy of these treatments shows that, roughly, monoclonal antibody treatments have the highest efficacy, followed by S1P receptor and fumarate drugs, with teriflunomide and the oldest standbys of INFß therapeutics and glatiramer with lowest benefit. This may change once the new oral drugs in Phase 3 trials are approved.

As many of these products diminish immune function, significant risk with infections or reactivation of chronically suppressed diseases is present. Most notably with drugs that block immune entry across the blood-brain barrier, this includes reactivation of the JC virus, resulting in progressive multifocal leukoencephalopathy (PML), which can be devastating to function and require cessation of therapy.52 This does also include chronic hepatitis B and C reactivation,53,54 varicella zoster,55 and HHV-6,56 among others.

Acute MS flares are treated with immune suppression, typically taking one of three forms. High dose IV/PO steroids were the first treatment identified and work well, however, many patients exist that may not be able to tolerate their side effects.57 A similar option is use of high dose purified adrenocorticotropic hormone injections that induce the body to secrete steroids directly; however, this is very expensive and many locations do not have access to this therapy.57 The last option is plasmapheresis which exchanges the plasma in the patient’s blood to remove circulating antibodies, cytokines, and inflammatory biomarkers. This does have good evidence but is typically recommended when steroids are not sufficiently treating a flare.57 IVIG has been trialed in the past but lacks high-quality evidence to support its use.

Outside of treating the underlying cause, medical therapy mainly focuses on treating the effects of MS flares to minimize disability. Optimal treatment for MS patients should include physical therapy to maximize function and accelerate return to maximal baseline.58 This should also include occupational therapy as progressive accommodations will become necessary as disability accumulates to allow for best function and quality of life.59 Key disability to watch for includes spastic bladder with bladder infections, loss of bowel control or motility, vertiginous symptoms, fatigue, new chronic pain and paresthesia, sexual functioning, muscular spasticity/tremors/gait problems and concomitant depression. An excellent summary of current medications for these symptoms and their use may be found through the National Multiple Sclerosis Society.41 Dysphagia in MS is common with prevalence of 43%, requiring use of regular screening and speech- language pathology for evaluation and therapeutic treatment.60

Use of OMT for MS patients should focus on restoring as much homeostatic balance as possible. Because mobility is limited in many MS patients, opening the thoracic inlet is a low complexity intervention that can improve biomechanics and respirations along with lymphatic flow. Similarly, sacral rock/sacral wobble can help with parasympathetic tone and aid with GI functioning, which is likely to be affected either primarily by MS damage or secondarily by low gut motility from decreased activity overall.61 Several pilot studies exist that look at other OMT interventions with improvement in quality of life overall. Additionally, assessment from OMT first principles would imply that use of counterstrain, muscle energy, the Still technique and others should be of use for the muscle tension and spasticity seen from loss of innervation or changes to gait mechanics from MS progression. This is likely to be a fruitful topic of future osteopathic research.

CONCLUSION

Multiple sclerosis is a complex autoimmune disease with each flare carrying the risk of additional disability. Early detection and awareness of the disease in the differential, even for common problems like anxiety/depression, gait changes, and tremor, is key for primary care providers. Imaging early with MRI if you have suspicion of MA is the mainstay for diagnosis, with more specialized labs such as CSF specific oligoclonal bands now playing an increased role in early diagnosis. DO providers should use OMT to help their patients with MS, along with utilizing a multidisciplinary team of physical therapists, occupational therapists, speech language pathologists, and other specialists to aid in maximizing function as the disease progresses. Refer to neurology early to get new therapeutics initiated. Most importantly as a DO, it is important to provide care to the entire patient, with emotional and spiritual support as necessary as the patient deals with a significant and debilitating diagnosis.

ACKNOWLEDGEMENTS

Special thanks to Lindsay Flegge, MSW, PhD, pain psychologist at Mary Free Bed and wife of the first author, for her work in editing for clarity and formatting of the manuscript of this paper.

REFERENCES


  1. Wallin MT, Culpepper WJ, Campbell JD, et al. The prevalence of MS in the United States: A population-based estimate using health claims data. Neurology. 2019;92(10):e1029–e1040. doi:10.1212/ WNL.0000000000007035

  2. Willer CJ, Dyment DA, Risch NJ, Sadovnick AD, Ebers GC. Canadian Collaborative Study Group. Twin concordance and sibling recurrence rates in multiple sclerosis. Proc Natl Acad Sci USA. 2003;100(22): 12877–12882. doi:10.1073/pnas.1932604100

  3. Guan Y, Jakimovski D, Ramanathan M, Weinstock-Guttman B, Zivadinov R. The role of Epstein-Barr virus in multiple sclerosis: From molecular pathophysiology to in vivo imaging. Neural Regen Res. 2019;14(3): 373–386. doi:10.4103/1673-5374.245462

  4. Leibovitch EC, Jacobson S. Evidence linking HHV-6 with multiple sclerosis: An update. Curr Opin Virol. 2014;9:127–133. doi:10.1016/ j.coviro.2014.09.016

  5. Cossu D, Yokoyama K, Hattori N. Bacteria–host interactions in multiple sclerosis. Front. Microbiol. 9:2966. doi:10.3389/fmicb.2018.02966

  6. Laitinen OH, Honkanen H, Pakkanen O, et al. Coxsackievirus B1 is associated with induction of ß-cell autoimmunity that portends type 1 diabetes. Diabetes. 2014;63(2):446–455. doi:10.2337/db13-0619

  7. Sintzel MB, Rametta M, Reder AT. Vitamin D and multiple sclerosis: A comprehensive review. Neurol Ther. 2018;7(1):59–85. doi:10.1007/ s40120-017-0086-4

  8. Mora J, Iwata M, von Andrian U. Vitamin effects on the immune system: vitamins A and D take centre stage. Nat Rev Immunol. 2008;8(9):685–698. doi:10.1038/nri2378

  9. Wingerchuk DM. Smoking: effects on multiple sclerosis susceptibility and disease progression. Ther Adv Neurol Disord. 2012;5(1):13–22. doi:10.1177/1756285611425694

  10. Huppke B, Ellenberger D, Hummel H, et al. Association of obesity with multiple sclerosis risk and response to first-line disease modifying drugs in children. JAMA Neurol. 2019;76(10):1157–1165. doi:10.1001/ jamaneurol.2019.1997

  11. Kasper LH, Shoemaker J. Multiple sclerosis immunology: The healthy immune system vs the MS immune system. Neurology. 2010;74 Suppl 1:S2–8. doi:10.1212/WNL.0b013e3181c97c8f

  12. Kouchaki E, Salehi M, Reza Sharif M, Nikoueinejad H, Akbari H. Numerical status of CD4(+)CD25(+)FoxP3(+) and CD8(+)CD28(-) regulatory T cells in multiple sclerosis. Iran J Basic Med Sci. 2014;17(4):250–255. PMID: 24904717

  13. van Langelaar J, Rijvers L, Smolders J, van Luijn MM (2020) B and T cells driving multiple sclerosis: Identity, mechanisms and potential triggers. Front Immunol. 11:760. doi:10.3389/fimmu.2020.00760

  14. Gandhi R, Laroni A, Weiner HL. Role of the innate immune system in the pathogenesis of multiple sclerosis. J Neuroimmunol. 2010;221(1–2): 7–14. doi:10.1016/j.jneuroim.2009.10.015

  15. Kurnellas MP, Donahue KC, Elkabes S. Mechanisms of neuronal damage in multiple sclerosis and its animal models: role of calcium pumps and exchangers. Biochem Soc Trans. 2007;35(Pt 5):923–926. doi:10.1042/ BST0350923

  16. Lassmann H. Multiple sclerosis pathology. Cold Spring Harb Perspect Med. 2018;8(3):a028936. doi:10.1101/cshperspect.a028936

  17. Gelfand JM. Multiple sclerosis: diagnosis, differential diagnosis and clinical presentation. Handb Clin Neurol. 2014;122:269–290. doi:10.1016/B978-0-444-52001-2.00011-X

  18. Langer-Gould A, Popat RA, Huang SM, et al. Clinical and demographic predictors of long-term disability in patients with relapsing-remitting multiple sclerosis: A systematic review. Arch Neurol. 2006;63(12): 1686–1691. doi:10.1001/archneur.63.12.1686

  19. Expanded Disability Status Scale (EDSS). Multiple Sclerosis Trust. https://mstrust.org.uk/a-z/expanded-disability-status-scale-edss. Published 01/2020.

  20. Gani R, Nixon RM, Hughes S, Jackson CH. Estimating the rates of disability progression in people with active relapsing-remitting multiple sclerosis. Journal of Medical Economics. 2007;10(2):79-89. doi:10.3111/200710079089

  21. Paz Soldán MM, Novotna M, Abou Zeid N, et al. Relapses and disability accumulation in progressive multiple sclerosis. Neurology. 2015;84(1): 81–88. doi:10.1212/WNL.0000000000001094

  22. Kaufmann M, Kuhle J, Puhan MA, et al. Factors associated with time from first-symptoms to diagnosis and treatment initiation of Multiple Sclerosis in Switzerland. Mult Scler J Exp Transl Clin. 2018;4(4):2055217318814562. doi:10.1177/2055217318814562

  23. Ghasemi N, Razavi S, Nikzad E. Multiple sclerosis: Pathogenesis, symptoms, diagnoses and cell-based therapy. Cell J. 2017;19(1):1–10. doi:10.22074/cellj.2016.4867

  24. Schumacher GA, Beebe G, Kibler RF, et al. Problems of experimental trials of therapy in multiple sclerosis: Report by the panel on the evaluation of experimental trials of therapy in multiple sclerosis. Ann N Y Acad Sci. 1965;122:552–568. doi:10.1111/j.1749-6632.1965.tb20235.x

  25. McDonald WI, Compston A, Edan G, et al. Recommended diagnostic criteria for multiple sclerosis: Guidelines from the international panel on the diagnosis of multiple sclerosis. Ann Neurol. 2001;50(1):121–127. doi:10.1002/ana.1032

  26. Carroll WM. 2017 McDonald MS diagnostic criteria: Evidence-based revisions. Mult Scler. 2018;24(2):92–95. doi:10.1177/1352458517751861

  27. Wattjes MP, Ciccarelli O, Reich DS, et al. 2021 MAGNIMS-CMSC-NAIMS consensus recommendations on the use of MRI in patients with multiple sclerosis. Lancet Neurol. 2021;20(8):653–670. doi:10.1016/S1474- 4422(21)00095-8

  28. Brooks JA, McCudden C, Breiner A, Bourque PR. Causes of albuminocytological dissociation and the impact of age-adjusted cerebrospinal fluid protein reference intervals: A retrospective chart review of 2627 samples collected at tertiary care centre. BMJ Open. 2019;9(2):e025348. doi:10.1136/bmjopen-2018-025348

  29. Deisenhammer F, Zetterberg H, Fitzner B, Zettl UK. The cerebrospinal fluid in multiple sclerosis. Front Immunol. 2019;10:726. doi:10.3389/ fimmu.2019.00726

  30. Comi G, Leocani L, Medaglini S, et al. Measuring evoked responses in multiple sclerosis. Mult Scler. 1999;5(4):263–267. doi:10.1177/135245859900500412

  31. Lublin FD, Reingold SC, Cohen JA, et al. Defining the clinical course of multiple sclerosis: The 2013 revisions. Neurology. 2014;83(3):278–286. doi:10.1212/WNL.0000000000000560

  32. Ömerhoca S, Akkaş SY, İçen NK. Multiple sclerosis: Diagnosis and differential diagnosis. Noro Psikiyatr Ars. 2018;55(Suppl 1):S1–S9. doi:10.29399/npa.23418

  33. Lindland ES, Solheim AM, Andreassen S, et al. Imaging in Lyme neuroborreliosis. Insights Imaging. 2018;9(5):833–844. doi:10.1007/ s13244-018-0646-x

  34. Uygunoğlu U, Siva A. Behçet’s syndrome and nervous system involvement. Curr Neurol Neurosci Rep. 2018;18(7):35. doi:10.1007/s11910-018-0843-5

  35. Kim SS, Richman DP, Johnson WO, Hald JK, Agius MA. Limited utility of current MRI criteria for distinguishing multiple sclerosis from common mimickers: primary and secondary CNS vasculitis, lupus and Sjogren’s syndrome. Mult Scler. 2014;20(1):57–63. doi:10.1177/1352458513491329

  36. Briani C, Dalla Torre C, Citton V, et al. Cobalamin deficiency: clinical picture and radiological findings. Nutrients. 2013;5(11):4521–4539. doi:10.3390/nu5114521

  37. Plantone D, Primiano G, Renna R, et al. Copper deficiency myelopathy: A report of two cases. J Spinal Cord Med. 2015;38(4):559–562. doi:10.1179/2045772314Y.0000000268

  38. Stojanov D, Vojinovic S, Aracki-Trenkic A, et al. Imaging characteristics of cerebral autosomal dominant arteriopathy with subcortical infarcts and leucoencephalopathy (CADASIL). Bosn J Basic Med Sci. 2015;15(1):1–8. doi:10.17305/bjbms.2015.247

  39. Algahtani H, Shirah B, Amin M, Altarazi E, Almarzouki H. Susac syndrome misdiagnosed as multiple sclerosis with exacerbation by interferon beta therapy. Neuroradiol J. 2018;31(2):207–212. doi:10.1177/1971400917712265

  40. Roohani P, Emiru T, Carpenter A, et al. Late onset multiple sclerosis: Is it really late onset? Mult Scler Relat Disord. 2014;3(4):444–449. doi:10.1016/j.msard.2014.02.004

  41. Medications. National Multiple Sclerosis Society. https://www.nationalmssociety.org/Treating-MS/Medications.

  42. Chaudhry BZ, Cohen JA, Conway DS. Sphingosine 1-Phosphate receptor modulators for the treatment of multiple sclerosis. Neurotherapeutics. 2017;14(4):859–873. doi:10.1007/s13311-017-0565-4

  43. Mills EA, Ogrodnik MA, Plave A, Mao-Draayer Y. Emerging understanding of the mechanism of action for dimethyl fumarate in the treatment of multiple sclerosis. Front Neurol. 2018;9:5. doi:10.3389/fneur.2018.00005

  44. Bar-Or A, Pachner A, Menguy-Vacheron F, Kaplan J, Wiendl H. Teriflunomide and its mechanism of action in multiple sclerosis. Drugs. 2014;74(6):659–674. doi:10.1007/s40265-014-0212-x

  45. Leist TP, Weissert R. Cladribine: Mode of action and implications for treatment of multiple sclerosis. Clin Neuropharmacol. 2011; 34(1): 28–35. doi:10.1097/WNF.0b013e318204cd90

  46. Dhib-Jalbut S, Marks S. Interferon-ß mechanisms of action in multiple sclerosis. Neurology. 2010;74(1 Supplement 1):S17–S24. doi:10.1212/ WNL.0b013e3181c97d99

  47. Weber MS, Hohlfeld R, Zamvil SS. Mechanism of action of glatiramer acetate in treatment of multiple sclerosis. Neurotherapeutics. 2007;4:647–653. doi:10.1016/j.nurt.2007.08.002

  48. Boross P, Leusen JH. Mechanisms of action of CD20 antibodies. Am J Cancer Res. 2012;2(6):676–690. PMID: 23226614

  49. Hu Y, Turner MJ, Shields J, et al. Investigation of the mechanism of action of alemtuzumab in a human CD52 transgenic mouse model. Immunology. 2009;128(2):260–270. doi:10.1111/j.1365-2567.2009.03115.x

  50. González-Amaro R, Mittelbrunn M, Sánchez-Madrid F. Therapeutic anti-integrin (alpha4 and alphaL) monoclonal antibodies: two-edged swords?. Immunology. 2005;116(3):289–296. doi:10.1111/j.1365-2567.2005.02225.x

  51. Fox EJ. Mechanism of action of mitoxantrone. Neurology. 2004;63(12 Suppl 6):S15–S18. doi:10.1212/wnl.63.12_suppl_6.s15

  52. Williamson EML, Berger JR. Diagnosis and treatment of progressive multifocal leukoencephalopathy associated with multiple sclerosis therapies. Neurotherapeutics. 2017;14(4):961–973. doi:10.1007/ s13311-017-0570-7

  53. Tagawa A, Ogawa T, Tetsuka S, et al. Hepatitis C virus (HCV) reactivation during fingolimod treatment for relapsing and remitting multiple sclerosis. Mult Scler Relat Disord. 2016;9:155–157. doi:10.1016/ j.msard.2016.08.003

  54. Ciardi MR, Iannetta M, Zingaropoli MA, et al. Reactivation of Hepatitis B Virus With Immune-Escape Mutations After Ocrelizumab Treatment for Multiple Sclerosis. Open Forum Infect Dis. 2018;6(1):ofy356. doi:10.1093/ ofid/ofy356

  55. Arvin AM, Wolinsky JS, Kappos L, et al. Varicella-zoster virus infections in patients treated with fingolimod: risk assessment and consensus recommendations for management. JAMA Neurol. 2015;72(1):31–39. doi:10.1001/jamaneurol.2014.3065

  56. Yao K, Gagnon S, Akhyani N, et al. Reactivation of human herpesvirus-6 in natalizumab treated multiple sclerosis patients. PLoS One. 2008;3(4):e2028. doi:10.1371/journal.pone.0002028

  57. Ontaneda D, Rae-Grant AD. Management of acute exacerbations in multiple sclerosis. Ann Indian Acad Neurol. 2009;12(4):264–272. doi:10.4103/0972-2327.58283

  58. Řasová K, Freeman J, Cattaneo D, et al. Content and delivery of physical therapy in multiple sclerosis across Europe: A survey. Int J Environ Res Public Health. 2020;17(3):886. doi:10.3390/ijerph17030886

  59. Quinn É, Hynes SM. Occupational therapy interventions for multiple sclerosis: A scoping review. Scand J Occup Ther. 2021;28(5):399–414. doi:10.1080/11038128.2020.1786160

  60. Ansari NN, Tarameshlu M, Ghelichi L. Dysphagia in multiple sclerosis patients: Diagnostic and evaluation strategies. Degener Neurol Neuromuscul Dis. 2020;10:15–28. doi:10.2147/DNND.S198659

  61. Wolf K, Krinard T, Talsma J, Pierce-Talsma S. OMT for patients with multiple sclerosis. J Am Osteopath Assoc. 2017;117(12):e141. doi:10.7556/jaoa.2017.153