Contrast-enhanced Magnetic Resonance Imaging of the Lumbosacral Roots in the Dysimmune Inflammatory Polyneuropathies

The diagnosis of acute Guillain-Barre syndrome and chronic inflammatory demyelinating polyradiculoneuropathy is based on clinical characteristics, abnormalities on nerve conduction studies, and nerve biopsy specimens indicating demyelination. Inflammation and edema are also common findings in nerve specimens Immunotherapy is helpful in these dysimmune conditions. Occasionally the diagnosis is difficult to make, particularly when electrophysiological testing or nerve biopsy findings are not characteristic. The authors found contrast enhancement of lumbosacral roots in patients with chronic inflammatory demyelinating polyradiculoneuropathy and Guillain-Barre syndrome, but not m those with other demyelinating neuropathies. Contrast-enhanced magnetic resonance imaging could be a useful tool in the diagnosis of the dysimmune inflammatory neuropathies.     

Nerve conduction studies in polyneuropathy: practical physiology and patterns of abnormality

Nerve conduction studies are an essential part of the work-up of peripheral neuropathies. Many neuropathic syndromes can be suspected on clinical grounds, but optimal use of nerve conduction study techniques (in combination with needle electromyography) allows diagnostic classification and is therefore crucial to understanding and separation of neuropathies. Multifocal motor neuropathy, for example, may clinically present as ALS. Detection of evidence of demyelination (conduction blocks) leads to the correct diagnosis and to proper treatment. Nerve conduction studies provide essential information on (1) the spatial pattern of neuropathy, (2) the pattern of abnormalities distinguishing between primarily axonal and demyelinating pathology, and (3) the severity of neuropathic damage. This information is very comprehensive since many nerves and long segments of individual nerves can be sampled. Moreover the information is extremely detailed to the extent that the cellular pathology of a patient's neuropathy is usually defined best by physiological testing rather than by biopsy. Neuropathies can be generalized, focal, or multifocal; they can be symmetric or asymmetric; they can be distally predominant or proximal and distal. Primarily axonal neuropathies mainly affect sensory nerve and compound muscle action potential amplitudes, whereas demyelinating neuropathies lead to slowing of nerve conductions, and to increased temporal dispersion or conduction block. Usually, the pattern of demyelination allows to distinguish hereditary (uniform demyelination) from acquired (segmental demyelination) neuropathies. Electrodiagnostic criteria for primary demyelination are helpful to identify acquired demyelinating neuropathies.     

Review of the evolution of electrodiagnostic criteria for chronic inflammatory demyelinating polyradicoloneuropathy

Chronic inflammatory demyelinating polyradicoloneuropathy (CIDP) is a treatable form of neuropathy. Efforts to devise sets of electrodiagnostic (nerve conduction) criteria to distinguish primary demyelination from primary axonal neuropathies have been elusive, and at least 16 criteria have been proposed. Modifications to criteria frequently represent minor changes based on applying a set to a small number of patients with the clinical diagnosis of CIDP, whereas others are based on physiological changes related to demyelination and other pathophysiological features. The various modifications continue to result in limited sensitivity, likely related to the wide range of nerve conduction abnormalities among CIDP patients. Although some sets are appropriate for formal clinical drug trials, their complexity makes them difficult to apply in the clinic or electromyography laboratory. This study considers the evolution of the criteria, discusses their limitations, and ends with a simplified set of guidelines that can be applied in the clinic or laboratory.     

The F wave disappears due to impaired excitability of motor neurons or proximal axons in inflammatory demyelinating neuropathies.

OBJECTIVES--Investigation of pathophysiology of F wave disappearance in demyelinating neuropathies. METHODS--The peripheral motor nerve conduction was studied by motor evoked potential (MEP) on transcranial magnetic stimulation as well as conventional nerve conduction studies before and after the treatment in 26 patients with inflammatory demyelinating neuropathies. In addition, serum antiganglioside antibodies in the acute or active stage were examined. RESULTS--The F wave was abolished in 10 patients. Seven of the 10 patients showed motor evoked potentials (MEPs) on transcranial magnetic stimulation that ranged from 1-4 mV. In six of them the F wave reappeared in the recovery stage, but the MEP size did not change. This may be caused by humoral factors, because the F wave reappeared immediately after plasma exchange or intravenous immunoglobulin treatment. A correlation of F wave disappearance with the presence of serum antiganglioside antibodies was found. CONCLUSIONS--The major pathophysiology of F wave disappearance in demyelinating neuropathies is impairment of motor neuron excitability or prolonged refractoriness of the most proximal axon for backfiring. The conventional interpretation that absent F waves suggest a conduction block at the proximal site is often inadequate.     

Tumor necrosis factor-alpha antagonists and neuropathy

Tumor necrosis factor (TNF)-alpha plays an important role in many aspects of immune system development, immune-response regulation, and T-cell-mediated tissue injury. The evidence that TNF-alpha, released by autoreactive T cells and macrophages, may contribute to the pathogenesis of immune-mediated demyelinating neuropathies is reviewed. TNF-alpha antagonists (infliximab, etanercept, adalimumab) are indicated for the treatment of advanced inflammatory rheumatic and bowel disease, but these drugs can induce a range of autoimmune diseases that also attack the central and peripheral nervous systems. Case histories and series report on the association between anti-TNF-alpha treatment and various disorders of peripheral nerve such as Guillain-Barré syndrome, Miller Fisher syndrome, chronic inflammatory demyelinating polyneuropathy, multifocal motor neuropathy with conduction block, mononeuropathy multiplex, and axonal sensorimotor polyneuropathies. The proposed pathogeneses of TNF-alpha-associated neuropathies include both a T-cell and humoral immune attack against peripheral nerve myelin, vasculitis-induced nerve ischemia, and inhibition of signaling support for axons. Most neuropathies improve over a period of months by withdrawal of the TNF-alpha antagonist, with or without additional immune-modulating treatment. Preliminary observations suggest that TNF-alpha antagonists may be useful as an antigen-nonspecific treatment approach to immune-mediated neuropathies in patients with a poor response to, or intolerance of, standard therapies, but further studies are required.     

Immunneuropathien

The Guillain-Barré syndrome (GBS) and chronic inflammatory demyelinating polyneuropathy (CIDP) are the most common immune-mediated polyneuropathies, which can show variable clinical and electrophysiological manifestations. Rarer immune-mediated neuropathies encompass paraproteinemic neuropathies (PPN), multifocal motor neuropathy (MMN) and vasculitic neuropathies. The diagnosis usually relies on the history of symptom evolution, distribution of nerve dysfunction and particularly on characteristic features in nerve conduction studies, aided by cerebrospinal fluid (CSF) examination and nerve biopsy findings. The therapeutic toolbox encompasses corticosteroids, immunoglobulins and plasmapheresis often accompanied by long-term immunosuppression. It is important to note that immune-mediated neuropathies selectively respond to treatment and contraindications need to be considered. Despite treatment a considerable number of patients suffer from permanent neurological deficits.     

Reversible conduction block in human ischemic neuropathy after ergotamine abuse.

Conduction block [a significant reduction in compound muscle action potential (CMAP) amplitude after proximal compared to distal stimulation] is often found in demyelinating neuropathies, including inflammatory neuropathies and degenerative neuropathies, such as "liability to pressure neuropathy." There is experimental evidence that a transient conduction block can occur in rats after ischemic lesions of peripheral nerves are induced either by ligation of arterial vessels supplying nerve trunks, or by injection of arachidonic acid into peripheral arterial vessels. Conduction block has also recently been described in cases with necrotizing vasculitis. To date, however, no example of a reversible conduction block has been reported in human ischemic neuropathy.     

Electrophysiology in demyelinating polyneuropathies

Demyelinating neuropathies are disorders of the peripheral nervous system in which the myelin sheath of axons is affected by immune-mediated or genetically determined processes. In single axons, demyelination yields conduction block due to extinction of action potentials or conduction slowing. Motor nerve conduction studies assess these phenomena in nerves, which consist of many axons. It is important to distinguish demyelinating from axonal polyneuropathies as this allows accurate diagnosis and institution of appropriate treatment. Immunological treatment in acquired demyelinating polyneuropathies is often successful. Criteria were developed for motor conduction velocity slowing and for conduction block, which assume demyelination if the findings cannot be explained by axon loss. Criteria-sets for the diagnosis of specific polyneuropathies require that several variables are consistent with demyelination in several nerves. However, these sets are based on expert opinion and have a low sensitivity such that treatable neuropathies may be underdiagnosed. Evidence-based sets are currently being developed. Axon loss is the main determinant of the clinical deficit in demyelinating neuropathies and, if its mechanisms are further elucidated, it may be prevented by pharmacological treatment. Excitability testing, which assesses axonal membrane potential and ion-channel activities, may reveal some of these mechanisms.     

Intérêt de l’EMG dynamique dans le suivi des polyneuropathies dysimmunes chroniques

Nerve conduction studies providing insight into demyelinating process are essential for the diagnostic of chronic inflammatory demyelinating polyradiculoneuropathy. For the diagnostic, several sets of electrophysiologic criteria have been established. To assess the response to treatment, nerve conduction studies are often used in trials and in clinical practice. Nevertheless, the useful of these classical electrophysiologic techniques is debated because of their lack of sensibility and specificity. In the last 20 years, several works have showed that dysfunction of channels and pump of the axonal membrane at the site and around the site of the conduction block can precipitate conduction failure and produce weakness. These important features explaining clinical status are not correctly assessed by conventional nerve conduction studies. New nerve conduction examinations in dynamic conditions can explore these hyperexcitability modifications.     

Recent acquisitions in the treatment of chronic immune-mediated polyneuropathies

Chronic immune-mediated polyneuropathies encompass chronic inflammatory demyelinating polyneuropathies, polyneuropathies associated with monoclonal gammopathy and multifocal motor neuropathy with persistent conduction blocks. Their diagnosis is made on clinical, electrophysiological and sometimes immunochemical and pathological criteria. The efficacy of intravenous immunoglobulins has been reported in the short-term treatment of these neuropathies in the same way than corticosteroids and plasma exchanges, depending on the type of the polyneuropathy. The efficacy of long-term treatments needs further evaluation.     

Effective treatment of experimental autoimmune neuritis with human immunoglobulin

High-dose intravenous immunoglobulin (IVIg) is an effective treatment for inflammatory demyelinating neuropathies, although the mechanism(s) of action remain incompletely understood. Experimental autoimmune neuritis (EAN) is an animal model of inflammatory demyelinating neuropathies; however, there have been conflicting reports regarding the efficacy of human IVIg in EAN. To obtain a model suitable for the study of the mechanism(s) of action of IVIg in Guillain-Barré syndrome, we investigated the effect of IVIg in EAN in the rat using clinical, electrophysiological and morphological measures. Human IVIg administered at the onset of signs of disease proved effective in preventing further progression of disease and shortening disease duration. This effectiveness was associated with significant differences in electrophysiological parameters including less prolongation of somatosensory evoked potential (S wave) latencies, better maintained S wave amplitudes, less reduction of distal motor nerve conduction velocity, and better maintained amplitudes of compound muscle action potentials of the dorsal foot muscles after stimulation at ankle and hip. Moreover, treatment with IVIg resulted in significantly lower histological grades in rat EAN. The current study provides evidence that human IVIg is effective in the treatment of EAN in the rat, indicating that this model may facilitate further investigation of the mechanism(s) of action of IVIg in inflammatory demyelinating neuropathies.     

Differentiation between axonal and demyelinating neuropathies: Identical segments recorded from proximal and distal muscles

The presence of significant slowing of motor nerve conduction velocity is considered one of the electrodiagnostic hallmarks of demyelinating neuropathies; however, slowing of conduction velocity may also accompany severe axonal loss. When compound muscle action potential (CMAP) amplitudes are markedly reduced, it is frequently difficult to determine if conduction velocity slowing is due to axonal loss with dropout of the fastest conducting fibers or demyelination. To evaluate the relationship between conduction velocity and axonal dropout, we compared conduction velocities through the same segment of nerve recording from distal and proximal peroneal muscles in patients with chronic neuropathies, in patients with motor neuron disease, and in control subjects. In controls and patients with motor neuron disease, conduction velocities were normal with no significant difference between proximal and distal sites. In patients with axonal neuropathies, conduction velocities were preferentially slowed when recording from distal muscles and relatively normal when recording from proximal sites. Patients with demyelinating neuropathies showed marked slowing of conduction at both sites. We conclude that comparing conduction velocity obtained from proximal versus distal muscle recordings provides a simple, reliable aid for differentiating between chronic axonal and demyelinating polyneuropathies, especially in cases with conduction velocity slowing and low CMAP amplitudes. © 1995 John Wiley & Sons, Inc.     

Ultrasonography of MADSAM neuropathy: focal nerve enlargements at sites of existing and resolved conduction blocks

Using the emerging technique of peripheral nerve ultrasonography, multiple focal nerve swellings corresponding to sites of existing conduction blocks have been described in demyelinating polyneuropathies. We report two cases of multifocal acquired demyelinating sensory and motor neuropathy (MADSAM). In the first, multiple focal nerve enlargements were detected by ultrasound at sites of previous conduction blocks, well after complete clinical and electrophysiological resolution. In the second case, existing proximal conduction blocks could be localized by ultrasound. Our cases highlight the importance of nerve ultrasound in identifying conduction blocks and demonstrate that ultrasonographic morphological changes may outlast functional recovery in demyelinating neuropathies.     

Diagnosis and management of immune-mediated neuropathies

Immune-mediate neuropathies, or inflammatory neuropathies are neuropathies due to the dysregulation of the immune system. The injury to peripheral nerves can be divided into two phases: an early stage of immune injury, and a later stage of structural damage. The overall effects are axonal degeneration or demyelination depending on the target of immunological attacks. According to time course, there are two major types: Guillain-Barré syndrome (GBS) and chronic inflammatory demyelinating polyneuropathy (CIDP). Clinical manifestations of both diseases include progressive motor weakness and sensory disturbance with some variations among different patients. The major findings of nerve conduction studies on GBS patients are prolonged distal motor latencies and minimal F-wave latencies with variable reduction of nerve conduction velocities. In CIDP patients, slowed nerve conduction velocities are the usual findings in addition to prolongation of distal motor latencies and minimal F-wave latencies. Certain subtypes of immune-mediated neuropathies are associated with high titers of anti-gangliosdie antibodies. Patients with GBS and CIDP can benefit from immunotherapy. For GBS, plasma exchange and intravenous immunoglobulin (IVIG) are equally effective in reducing complications and neurological disability. Steroid of high dose is, however, harmful to GBS. Plasma exchange and IVIG can alleviate neurological deficits of CIDP with steroid to maintain the effects of plasma exchange and IVIG. In conclusion, careful clinical observations and judgment are the most important issue to manage patients with immune-mediated neuropathies.     

Proximal motor conduction evaluated by transcranial magnetic stimulation in acquired inflammatory demyelinating neuropathies.

OBJECTIVES: To evaluate conduction abnormalities in the proximal motor nerve in patients with acquired inflammatory demyelinating neuropathies by transcranial magnetic stimulation (TMS). METHODS: TMS intensity and background voluntary contraction (BVC) to evoke maximal size of motor evoked potential (MEP) in hand muscle were investigated in 24 normal subjects. Effect of experimentally induced conduction block by injecting local anesthetics in the peripheral nerve on MEP size was also studied in two normal subjects. In 22 patients with inflammatory demyelinating neuropathies, maximal MEPs were recorded in the deteriorating and recovery stages of the illness. RESULTS: In normal subjects, the MEP became maximal with 30-50% of maximal BVC and at more than 80% the maximal stimulator output of the 2.0 T circular coil. The change in MEP size well reflected the degree of conduction block induced by local anesthetics. Findings for patients suggested conduction abnormalities proximal to axilla in 9 patients, and that the abnormal reduction of Erb CMAP was the result of submaximal stimulation, not true conduction block, in 3 patients. The increase in MEP/wrist CMAP ratio was better correlated with improvement in muscle strength than with change in the axilla or Erb CMAP/wrist CMAP ratio. CONCLUSIONS: Problems such as conduction abnormalities in the motor tract of the central nervous system could not fully be excluded, but we consider that maximal MEP size can be used to predict proximal motor nerve conduction abnormalities.     

Giant nerves in chronic inflammatory polyradiculoneuropathy

Introduction: Nerve enlargement (NE) is described in inflammatory and inherited neuropathies. It is commonly multifocal and moderate in the former and homogeneous and generalized in the latter. We describe 4 cases of massive NE in inflammatory neuropathies. Methods: Patients presented with symptoms of polyneuropathy that progressed over months to years. Nerve conduction studies (NCS), laboratory analysis, nerve MRI, and nerve ultrasound were performed. Results: NCS revealed demyelinating neuropathy in all with multifocal conduction blocks or increased terminal latency indices. MRI/ultrasound revealed extensive NE in the roots and nerves. Detailed diagnostics including biopsies, positron emission tomography‐computed tomography, and genetic testing revealed no other pathology. Chronic inflammatory demyelinating polyneuropathy variants were diagnosed in all, and immunotherapies were successfully initiated. Conclusions: MRI and ultrasound contributed to diagnosis and therapy. All patients had giant NE in common, which strongly suggested inherited neuropathy. However, the final diagnosis was inflammatory neuropathy. Impressive NE can occur in immune‐mediated neuropathies and should be carefully differentiated from inherited neuropathies. Muscle Nerve 55 : 285–289, 2017     

Paraneoplastic syndromes of the peripheral nerves

PURPOSE OF REVIEW: To describe the paraneoplastic disorders of the motor and sensory nerves and neurons, and their immunologic associations. RECENT FINDINGS: Recently proposed diagnostic criteria for paraneoplastic disorders may assist in determining the likelihood a given neuropathy or neuronopathy is related to an underlying malignancy. Of this group of disorders, paraneoplastic sensory neuronopathies are the most frequent; many of these patients have anti-Hu antibodies and small-cell lung cancer. There is often motor, autonomic, or central nervous system involvement, and electrophysiological studies may demonstrate not only sensory changes, but also motor abnormalities. While cancer has been found more frequently than expected in patients with Guillain-Barré syndrome, this association is extremely rare. A limited number of reports have described chronic inflammatory demyelinating polyradiculoneuropathy, multifocal motor neuropathy with conduction block, vasculitic neuropathies, and motor neuron disease as paraneoplastic disorders. Anti-CV2 antibodies are frequently associated with a paraneoplastic sensorimotor axonal neuropathy and small-cell lung cancer. Peripheral nerve hyperexcitability may occur with or without a cancer association, and in both instances patients often have antibodies to voltage-gated potassium channels; thymoma and small-cell lung cancer are the most common underlying tumors. Plasma cell proliferative disorders are frequently associated with neuropathies, particularly demyelinating ones. SUMMARY: There is increasing recognition of an extensive variety of paraneoplastic disorders of the peripheral nerves. In many of these disorders onconeuronal antibodies are absent. Whole body fluorodeoxyglucose positron emission tomography scanning helps uncover the associated tumor, and recently proposed criteria may assist in the diagnosis. In many instances, prompt treatment of the tumor and immunotherapy result in symptom stabilization or neurologic improvement.     

Chronic inflammatory demyelinating neuropathies and their variants

The Chronic Inflammatory Demyelinating Polyradiculoneuropathies (CIDP) constitute a syndrome whose incidence is difficult to evaluate, and is probably underestimated. In the course of this presentation, we deliberately restricted discussion to issues raised in recent years concerning the extent of this syndrome. We discuss diagnostic criteria, especially electrophysiological ones. As the criteria proposed by the ad hoc committee of the American Academy of Neurology in 1991 have been questioned due to lack of sensitivity, new ones have been proposed recently. We briefly discuss the different types of chronic dysimmune demyelinating neuropathy: not only the CIDP, but also the Lewis and Sumner syndrome or multifocal inflammatory demyelinating neuropathy and the multiple conduction block neuropathies. At last, we point out the consistent finding of axonal involvement in the course of a chronic demyelinating neuropathy; over time, it can become predominant, which may make diagnosis difficult by suggesting a chronic axonal neuropathy that may be assumed to be primary. Consideration of these points may help clinicians recognize more chronic dysimmune neuropathies, for which immunosuppressive therapy has been found to be effective.     

Electrophysiological features of inherited demyelinating neuropathies: A reappraisal in the era of molecular diagnosis

The observation that inherited demyelinating neuropathies have uniform conduction slowing and that acquired disorders have nonuniform or multifocal slowing was made prior to the identification of mutations in myelin-specific genes which cause many of the inherited disorders involving peripheral nerve myelin. It is now clear that the electrophysiological aspects of these disorders are more complex than previously realized. Specifically, certain mutations appear to induce nonuniform slowing of conduction which resemble the findings in acquired demyelinating neuropathies. It is clinically important to recognize the different electrodiagnostic patterns of the various inherited demyelinating neuropathies. In addition, an understanding of the relationship between mutations of specific genes and their associated neurophysiological findings is likely to facilitate understanding of the role of these myelin proteins in peripheral nerve function and of how abnormalities in myelin proteins lead to neuropathy. We therefore review the current information on the electrophysiological features of the inherited demyelinating neuropathies in hopes of clarifying their electrodiagnostic features and to shed light on the physiological consequences of the different genetic mutations.