INTRODUCTION — Charcot-Marie-Tooth disease (CMT) consists of a spectrum of disorders caused by pathologic variants of various genes whose protein products are expressed in myelin and/or axonal structures within peripheral nerves.
This topic will review the management and prognosis of CMT. Other aspects of CMT are discussed separately. (See "Charcot-Marie-Tooth disease: Genetics, clinical features, and diagnosis".)
BACKGROUND — The genetics, clinical features, and diagnosis of CMT, summarized here briefly, are described in detail elsewhere. (See "Charcot-Marie-Tooth disease: Genetics, clinical features, and diagnosis".)
CMT is genetically heterogeneous. The major categories of CMT are CMT types 1 through 7 as well as an X-linked category, CMTX. Within each category, a specific disease associated with a particular gene is assigned a letter (eg, CMT1A, CMT1B, etc). CMT1 (demyelinating) and CMT2 (axonal) represent by far the largest proportion of patients (table 1).
The most common initial presentation of CMT is distal weakness and atrophy manifesting with foot drop and pes cavus. Sensory symptoms are often present but tend to be less prominent. Later in the course, foot deformities such as hammertoes ensue along with hand weakness and atrophy.
A comprehensive history and physical examination remain the core of ascertainment of and evaluation for cases of CMT (see "Charcot-Marie-Tooth disease: Genetics, clinical features, and diagnosis", section on 'When to suspect CMT'). Genetic testing is key to confirming the diagnosis after electrodiagnostic testing.
MANAGEMENT — Management of CMT is currently supportive; however, such supportive therapy can dramatically improve a patient's quality of life. Specific disease-modifying therapy is not available. Optimal management is multidisciplinary, with care provided by neurologists, genetic counselors, nurses, physical and occupational therapists, physiatrists, and orthopedic surgeons [1].
Rehabilitation — A comprehensive rehabilitation program plays a crucial role in the management of individuals affected by CMT [1]. All patients should be evaluated for weakness (both distal and proximal), physical conditioning, ambulation, balance, coordination, and manual dexterity. A major goal is the prevention of complications such as joint deformity and falls. Progressive resistance exercise programs may improve functional outcomes [2]. Daily stretching exercises early in the course of the disease may help delay ankle contractures. Occupational therapy can help to improve function with activities of daily living.
Orthotics, including ankle-foot orthoses, are often used to help stabilize the ankles and enhance gait function [3]. Orthopedic foot surgery may be beneficial for severe manifestations of pes cavus deformity and hammer toes, typically during adolescence or early adulthood.
However, there are only limited data from high-quality studies to support the utility of rehabilitation interventions for patients with CMT [4-6]. A systematic review published in 2016 identified only seven small randomized controlled trials and four small cohort studies examining physiotherapy or orthotics for patients with CMT [5]. There was evidence that mild to moderate endurance, stretching, and strength training exercises are safe for patients with CMT, can increase arm, pelvic girdle, and knee strength, and can improve performance with activities of daily living. Outcomes for orthotic interventions were mixed, but the one small trial that measured walking ability found that wearing plastic ankle-foot orthoses improved walking control compared with wearing ordinary shoes [7].
The role of vitamin supplementation — CMT is not directly associated with vitamin deficiencies, and supplementation has not been proven to be beneficial in traditional forms of CMT. However, patients with CMT who also have vitamin deficiencies that may cause neuropathy should receive appropriate replacement therapy to prevent worsening symptoms. (See 'Concomitant neuropathic conditions' below.)
Some patients with uncommon inherited neuropathies that may mimic CMT can respond to certain types of vitamin supplementation. As examples, Brown-Vialetto-van Laere disease (BVVL) is an autosomal recessive disease that may respond to riboflavin therapy [8]; a distinct syndrome associated with biallelic pathogenic variants in SLC5A6 may respond to a combination of biotin, pantothenic acid, and lipoic acid [9]. (See "Charcot-Marie-Tooth disease: Genetics, clinical features, and diagnosis", section on 'Differential diagnosis'.)
Avoid exacerbating factors
Concomitant neuropathic conditions — Patients with CMT may experience further impairments with disorders that cause or exacerbate neuropathy, a list that includes diabetes mellitus, vitamin deficiencies, and immune-mediated neuropathies [1]. Therefore, patients should be screened periodically for these conditions and treated promptly if any are detected. In particular, patients with CMT who experience unusually rapid progression of symptoms should be evaluated for a superimposed immune-mediated or inflammatory neuropathy.
Medications — Because patients with CMT have an existing peripheral neuropathy, they are considered to be more susceptible to injury when treated with standard "nontoxic" dosages of neurotoxic agents [10]. A systematic review published in 2006 identified 26 publications, mainly case reports or small case series, describing CMT exacerbation associated with toxic medications, of which 22 involved vincristine [11]. Acute worsening or onset of weakness in patients with CMT was observed after vincristine administration of 2 to 4 mg for adults or 1.5 mg/m2 per dose in children. Most of the patients had undiagnosed demyelinating forms of CMT (eg, CMT1A).
Thus, vincristine is considered to be a definite high-risk medication for patients with CMT, including those who are asymptomatic and/or undiagnosed. Vincristine has long been labeled as contraindicated for patients with demyelinating forms of CMT.
Data for other drugs are quite limited, but a list of medications considered to have moderate to significant risk for patients with CMT is as follows [11]:
●Cisplatin, carboplatin, oxaliplatin
●Colchicine (extended use)
●Dichloroacetate
●Gold salts
●Metronidazole/misonidazole (extended use)
●Nitrous oxide (inhalation abuse or vitamin B12 deficiency)
●Perhexiline (not used in the United States)
●Pyridoxine (high dose)
●Taxol (paclitaxel, docetaxel)
●Zalcitabine
A longer list of drugs of concern for patients with CMT, including drugs of uncertain or minor risk and negligible or doubtful risk, can be found online at the Charcot-Marie-Tooth Association website.
Uncertain risks with anesthesia — Regional anesthesia has been controversial due to theoretical concerns that patients with CMT may have an increased susceptibility to further nerve damage with the use of local anesthetic agents [12]. However, the available limited clinical data suggest otherwise. A number of small case series and case reports have described uneventful outcomes with regional anesthesia, including both peripheral nerve and neuraxial blocks [13-16].
Investigational therapies — Experimental therapies are being tested in both animal models and human participants. This includes neurotropic and symptomatic medications as well as viral vectors to deliver both primary genes and gene-silencing agents. Some such experimental agents include:
●Progesterone antagonists may reduce overexpression of PMP22 and slow disease progression [17,18]. Progesterone can increase PMP22 expression, and studies in humans have suggested disease exacerbation in pregnancy, a setting in which plasma progesterone increases up to 10-fold [19]. Observations in an animal model were consistent with these findings as the administration of progesterone resulted in a more progressive neuropathy [17,18].
●Ascorbic acid (vitamin C), which is known to promote myelination, appeared promising in an animal model of CMT1A [20]. Ascorbic acid therapy reduced the expression of PMP22 to a level below that required to induce the disease. This change was associated with remyelination, amelioration of the CMT1A phenotype, and prolonged lifespan. However, there was no clear benefit of ascorbic acid in a 12-month randomized controlled trial of 81 children with CMT1A [21], in a similar trial of 179 adults with CMT1A [22], or in a smaller trial of 11 patients younger than age 25 years [23]. Since disease progression in CMT1A is typically slow, trials with longer treatment periods may be necessary to detect any benefit [24,25]. However, it is discouraging that any potential benefit would be that modest.
●Neurotrophin-3 (NT3) improved axonal regeneration and associated myelination in both a xenograft model of Schwann cells with a PMP22 duplication and in a mouse model with a pathogenic PMP22 single-nucleotide variant (SNV) [26]. In the same report, a single-blinded pilot clinical trial involving eight patients with CMT1A found that NT3 treatment for six months was associated with improved sural nerve myelinated fiber regeneration compared with placebo treatment.
●GARS has been the target of several preclinical studies. A study testing intramuscular AAV-mediated gene transfer of NT-3 into mice with pathogenic variants in GARS (modeling CMT2D) showed functional and electrophysiologic improvements [27]. AAV-mediated delivery of RNAi sequences targeting variant GARS mRNA into mouse models of CMT2D showed therapeutic effects, especially when treatment was administered at birth [28].
●Curcumin has been studied in a mouse model of CMT1A and led to rejuvenation of myelinated axons in this model [29].
●A compound oral agent consisting of baclofen, naltrexone, and D-sorbitol (PXT3003) in individuals with CMT1A showed benefit in the Overall Neuropathy Limitations Scale in a small clinical trial [30].
●MFN2 agonists have been found to improve mitochondrial defects in a mouse model of CMT2A [31].
●Antisense oligonucleotide suppression of PMP22 mRNA levels in a model of CMT1A [32] – A molecular approach for CMT1A is to silence the excess expression of PMP22. A study in a rat model of CMT1A showed improvement on functional and myelination measures after intraneural delivery of AAV2/9 carrying shRNAs targeting PMP22 mRNA [33]. In transgenic mouse models of CMT1A, administration of siRNA targeting PMP22 resulted in functional and histopathological improvement [34].
●Intrathecal gene therapy was studied in mouse models of CMTX1 replicating several different variants of GJB1, and the response varied significantly based on the specific variants represented [35].
●Direct gene replacement is a promising strategy for multiple forms of CMT [32]. A mouse model of CMT4J was dosed with AAV9 containing FIG4, showing good motor function, neurophysiologic outcomes, and histopathological findings [36]. Intrathecal injection of AAV9 carrying GJB1/Cx32 into Gjb1-null mice led to improved motor function and electrophysiologic parameters [37].
●One study using a CRISPR/Cas9 approach in a mouse model of CMT1A showed that TATA-box targeting of PMP22 led to downregulation of PMP22 expression and preservation of myelin and axons [38].
●Axonal neuregulin 1 type III (Nrg1TIII) promotes myelination via specific pathways including PI3K/Akt and MAPK/Erk. Genetic overexpression of Nrg1TIII was shown to improve neurophysiological and morphological parameters in a mouse model of CMT1B [39].
Outcome measures — Outcome measures are more relevant to clinical trials than to routine clinical care, but with the surge in investigational therapies and the growing interest in human clinical trials for CMT, it is important to establish commonly used outcome measures. For adults, a multi-item CMT Functional Outcome Measure (CMT-FOM) was validated [40], and other single-item and multi-item outcome measures have been studied [41]. Outcome measures have been proposed specifically for infants with CMT [42], including an alternate multi-item scale that was validated for this age group [43]. Electrophysiologic outcome measures could also potentially track progression and monitor for treatment effects. In addition to standard electrophysiologic measures, more advanced techniques such as motor unit number index (see "Overview of nerve conduction studies", section on 'Motor unit number estimates (MUNE)') may be considered for such purposes [44]. Imaging modalities such as magnetic resonance imaging (MRI) are being adopted for use as outcome measures and for monitoring of clinical progression in neuromuscular diseases, including CMT [45]. It is expected that these outcome measures will become increasingly used in clinical trials, and some of the individual measures may be useful for tracking disease progression during routine clinical care.
PROGNOSIS — CMT in most cases is characterized by onset in the first or second decade of life with very slow progression [46]. Disability generally increases with age, but there is considerable variability in age of onset, rate of progression, and clinical severity both between and within different CMT subtypes. Functional outcomes vary from minor impairments to severe lower limb atrophy and wheelchair dependence. Nevertheless, many patients retain at least partial ambulatory abilities for all or most of their lives, and it is rare for CMT to shorten life expectancy.
With CMT1A, the most common subtype, progression often results in gait difficulty, but complete loss of ambulation is uncommon, and life expectance is normal. (See "Charcot-Marie-Tooth disease: Genetics, clinical features, and diagnosis", section on 'CMT1'.)
With CMTX1, the second most common CMT subtype, disease progression to severe disability occurs on average by the fifth decade in males [47], but lifespan is not shortened [48]. Females with CMTX1 tend to have milder clinical courses. (See "Charcot-Marie-Tooth disease: Genetics, clinical features, and diagnosis", section on 'CMTX1'.)
Respiratory failure due to neuromuscular weakness of the diaphragm or vocal cords is a rare complication of CMT but has been reported in a number of subtypes of CMT, including CMT1A [46,49].
CMT has a major impact on the quality of life of affected individuals. A 2019 study from Germany of 397 patients with genetically confirmed diagnoses of CMT estimated that the total annual cost of illness per patient was USD $22,362 [50].
INFORMATION FOR PATIENTS — UpToDate offers two types of patient education materials, "The Basics" and "Beyond the Basics." The Basics patient education pieces are written in plain language, at the 5th to 6th grade reading level, and they answer the four or five key questions a patient might have about a given condition. These articles are best for patients who want a general overview and who prefer short, easy-to-read materials. Beyond the Basics patient education pieces are longer, more sophisticated, and more detailed. These articles are written at the 10th to 12th grade reading level and are best for patients who want in-depth information and are comfortable with some medical jargon.
Here are the patient education articles that are relevant to this topic. We encourage you to print or email these topics to your patients. (You can also locate patient education articles on a variety of subjects by searching on "patient info" and the keyword(s) of interest.)
●Basics topic (see "Patient education: Charcot-Marie-Tooth disease (The Basics)")
SUMMARY AND RECOMMENDATIONS
●Management – Specific therapy for Charcot-Marie-Tooth disease (CMT) is not yet available. Optimal management is multidisciplinary. (See 'Management' above.)
•A comprehensive rehabilitation program plays a crucial role in the management of individuals affected by CMT. Stretching, endurance, and strengthening exercises and orthotics may help to improve function. (See 'Rehabilitation' above.)
•Patients with CMT should be screened periodically for conditions that cause or exacerbate neuropathy, such as diabetes mellitus, vitamin deficiencies, and superimposed immune-mediated neuropathies. (See 'Concomitant neuropathic conditions' above.)
•Patients with CMT should avoid drugs that can exacerbate neuropathy, particularly vincristine. (See 'Medications' above.)
●Prognosis – CMT in most cases is characterized by onset in the first or second decade of life with very slow progression. Disability generally increases with age. However, there is considerable variability in age of onset, rate of progression, and clinical severity, both between and within different CMT subtypes. (See 'Prognosis' above.)
1 : Charcot-Marie-Tooth disease and other inherited neuropathies.
2 : Safety and efficacy of progressive resistance exercise for Charcot-Marie-Tooth disease in children: a randomised, double-blind, sham-controlled trial.
3 : The impact of orthoses on gait in children with Charcot-Marie-Tooth disease.
4 : Treatment for Charcot-Marie-Tooth disease.
5 : Rehabilitation Management of the Charcot-Marie-Tooth Syndrome: A Systematic Review of the Literature.
6 : Systematic review of exercise for Charcot-Marie-Tooth disease.
7 : Assessment of appropriate ankle-foot orthoses models for patients with Charcot-Marie-Tooth disease.
8 : Brown-Vialetto-Van Laere syndrome, a ponto-bulbar palsy with deafness, is caused by mutations in c20orf54.
9 : Novel biallelic variants expand the SLC5A6-related phenotypic spectrum.
10 : Toxic neuropathy in patients with pre-existing neuropathy.
11 : Medication-induced exacerbation of neuropathy in Charcot Marie Tooth disease.
12 : First, do no harm: balancing the risks and benefits of regional anesthesia in patients with underlying neurological disease.
13 : Charcot-Marie-Tooth disease: peripartum management of two contrasting clinical cases.
14 : Ultrasound-guided peripheral regional blockade in patients with Charcot-Marie-Tooth disease: a review of three cases.
15 : Anesthetic management of an obstetric patient with Charcot-Marie-Tooth disease: a case study.
16 : Anesthetic Management of a Patient With Charcot-Marie-Tooth Disease.
17 : Therapeutic administration of progesterone antagonist in a model of Charcot-Marie-Tooth disease (CMT-1A).
18 : Antiprogesterone therapy uncouples axonal loss from demyelination in a transgenic rat model of CMT1A neuropathy.
19 : Pregnancy and delivery in Charcot-Marie-Tooth disease type 1.
20 : Ascorbic acid treatment corrects the phenotype of a mouse model of Charcot-Marie-Tooth disease.
21 : Ascorbic acid for Charcot-Marie-Tooth disease type 1A in children: a randomised, double-blind, placebo-controlled, safety and efficacy trial.
22 : Effect of ascorbic acid in patients with Charcot-Marie-Tooth disease type 1A: a multicentre, randomised, double-blind, placebo-controlled trial.
23 : Oral high dose ascorbic acid treatment for one year in young CMT1A patients: a randomised, double-blind, placebo-controlled phase II trial.
24 : Charcot-Marie-Tooth disease type 1A: is ascorbic acid effective?
25 : Ascorbic acid for the treatment of Charcot-Marie-Tooth disease.
26 : NT-3 promotes nerve regeneration and sensory improvement in CMT1A mouse models and in patients.
27 : AAV1.NT-3 gene therapy in a CMT2D model: phenotypic improvements in GarsP278KY/+ mice.
28 : Allele-specific RNA interference prevents neuropathy in Charcot-Marie-Tooth disease type 2D mouse models.
29 : Oral curcumin mitigates the clinical and neuropathologic phenotype of the Trembler-J mouse: a potential therapy for inherited neuropathy.
30 : A double-blind, placebo-controlled, randomized trial of PXT3003 for the treatment of Charcot-Marie-Tooth type 1A.