key: cord-0906584-ezfvj2j3 authors: Koike, Haruki; Katsuno, Masahisa title: Macrophages and Autoantibodies in Demyelinating Diseases date: 2021-04-08 journal: Cells DOI: 10.3390/cells10040844 sha: e1978dafca2bdeaa0d1b44b354c5e34e94eff242 doc_id: 906584 cord_uid: ezfvj2j3 Myelin phagocytosis by macrophages has been an essential feature of demyelinating diseases in the central and peripheral nervous systems, including Guillain–Barré syndrome (GBS), chronic inflammatory demyelinating polyneuropathy (CIDP), and multiple sclerosis (MS). The discovery of autoantibodies, including anti-ganglioside GM1 antibodies in the axonal form of GBS, anti-neurofascin 155 and anti-contactin 1 antibodies in typical and distal forms of CIDP, and anti-aquaporin 4 antibodies in neuromyelitis optica, contributed to the understanding of the disease process in a subpopulation of patients conventionally diagnosed with demyelinating diseases. However, patients with these antibodies are now considered to have independent disease entities, including acute motor axonal neuropathy, nodopathy or paranodopathy, and neuromyelitis optica spectrum disorder, because primary lesions in these diseases are distinct from those in conventional demyelinating diseases. Therefore, the mechanisms underlying demyelination caused by macrophages remain unclear. Electron microscopy studies revealed that macrophages destroy myelin as if they are the principal players in the demyelination process. Recent studies suggest that macrophages seem to select specific sites of myelinated fibers, including the nodes of Ranvier, paranodes, and internodes, for the initiation of demyelination in individual cases, indicating that specific components localized to these sites play an important role in the behavior of macrophages that initiate myelin phagocytosis. Along with the search for autoantibodies, the ultrastructural characterization of myelin phagocytosis by macrophages is a crucial step in understanding the pathophysiology of demyelinating diseases and for the future development of targeted therapies. Macrophages play an important role, not only in normal immune system maintenance, but also in pathological conditions. Myelin phagocytosis by macrophages has been an essential feature of demyelinating diseases in the central and peripheral nervous systems, including Guillain-Barré syndrome (GBS), chronic inflammatory demyelinating polyneuropathy (CIDP), and multiple sclerosis (MS) [1] [2] [3] [4] [5] . Particularly, early ultrastructural studies, using biopsy specimens from patients with GBS and CIDP, have demonstrated the stripping of morphologically normal myelin lamellae by cytoplasmic processes of macrophages [1, 6] . These macrophages caused researchers to assume that they are active players in the disease process, rather than mere scavengers of unnecessary materials. The discovery of autoantibodies directed against the constituents of the nervous system, by later researchers, contributed to the understanding of the disease process in a subpopulation of patients diagnosed with these diseases. For example, a concept that molecular mimicry between gangliosides located at the axolemma and the surface epitopes of exogenous pathogens induces the production of anti-ganglioside antibodies has been established in the axonal form of GBS [7] . Recent studies revealed that IgG4 autoantibodies against paranodal junction proteins found in a subpopulation of patients diagnosed with CIDP cause aberrant nerve conduction owing to paranodal dissection [8, 9] . Regarding diseases of the central nervous system, anti-aquaporin 4 (AQP4) antibodies were found to be positive in patients with neuromyelitic optica [10] . However, lesions in the nervous system caused by these antibodies are distinct from those of conventional demyelination caused by macrophages [8, 11, 12] . Hence, the mechanisms underlying demyelination owing to myelin phagocytosis by macrophages remain unclear. In this article, the mechanisms of demyelinating diseases are described by focusing on the role of macrophages and autoantibodies. GBS is an acute polyneuropathy, which typically occurs following infection [13] . This disease was initially considered to be a demyelinating neuropathy, called acute inflammatory demyelinating polyneuropathy (AIDP), because a previous report demonstrated demyelinating lesions owing to myelin phagocytosis by macrophages [1] . Later studies revealed the presence of an axonal counterpart without the macrophage-associated demyelination as another form of GBS [11, 14, 15] . This axonal form of GBS is called acute motor axonal neuropathy (AMAN) or acute motor sensory axonal neuropathy depending on the absence or presence of sensory involvement [11] . The concept of molecular mimicry was established through studies on AMAN with anti-ganglioside GM1 antibodies that occurred after a Campylobacter jejuni infection [13] . The widely accepted theories are that the attachment of IgG autoantibodies to GM1, which is localized to the axolemma of motor fibers, and subsequent activation of complement cascades result in motor dysfunction in patients with AMAN [13, 16, 17] . Although the autopsy specimens revealed the presence of macrophages in the periaxonal space, macrophage-associated demyelinating lesions were not found in patients with AMAN [11] . Conversely, an association between specific autoantibodies with the occurrence of macrophage-associated demyelination in AIDP has not been clearly demonstrated. However, the presence of antecedent infections in patients with AIDP is similar to that in patients with AMAN, which indicates similar immunological processes [18] . An association between antibodies against moesin, which is expressed in the microvilli of Schwann cells at the nodes of Ranvier, and AIDP has been suggested after cytomegalovirus infection [19] . An increased occurrence of AIDP after the Zika virus infection has also been demonstrated [20] . Although an association between a specific anti-ganglioside antibody and Zika virus-related GBS has not been demonstrated [21] , peptide sharing was suggested among proteins of the Zika virus, cytomegalovirus, and the human peripheral nervous system [22, 23] . Recently, a conflicting discussion on the association between SARS-CoV2 infection (i.e., and AIDP has become a topic of research [24] [25] [26] . CIDP has been a chronic counterpart of AIDP because similar macrophage-associated demyelination was reported as a pathological hallmark [2, 4] . In contrast to AIDP, this disease is rarely accompanied by antecedent infections. CIDP was initially defined as neuropathy with a diffuse weakness of the limbs [2, 27] . This classic form of CIDP was designated as "typical CIDP" in the criteria proposed by the European Federation of Neurological Societies and Peripheral Nerve Society (EFNS/PNS) and it is now frequently used in daily practice [28] . In addition to the typical CIDP, the EFNS/PNS criteria define five forms of "atypical CIDP", which comprised multifocal acquired demyelinating sensory and motor (MADSAM), distal acquired demyelinating symmetric (DADS), pure sensory, pure motor, and focal subtypes [28] . Macrophage-associated demyelination was found not only in a typical CIDP but also in major atypical CIDP subtypes, including MADSAM, DADS, and pure sensory subtypes-although it is not found in all patients [29] . Recent studies demonstrated the presence of autoantibodies against paranodal junction components, including neurofascin 155 and contactin 1, in some patients diagnosed with typical CIDP and DADS [8, [30] [31] [32] [33] [34] . In patients with these antibodies, aberrant nerve conduction is caused by the detachment of paranodal myelin terminal loops from the axolemma resulting from the deposition of autoantibodies to the paranodal junctions [4, 8, 35, 36] . Unlike AMAN, the deposition of complements is not found at the paranodes because the immunoglobulin subclass of these antibodies is IgG4 [8] . Because classical demyelinating lesions associated with macrophages are not observed in patients with these antibodies, the concept of nodopathy or paranodopathy has recently been proposed for these patients [9, 34] . However, patients with these antibodies constitute a minority in the total CIDP population [8, 32, 33] . The mechanisms underlying macrophage-associated demyelination remain to be elucidated. MS is an inflammatory demyelinating disease of the central nervous system [3, 37] . Based on the mode of progression, this disease is classified into four types: clinically isolated syndrome, relapsing remitting MS, primary progressive MS, and secondary progressive MS [38] . Although MS has traditionally been considered a disease mediated by T cells, particularly CD4-positive T cells reactive to myelin antigens [39] , a recent study regarding the efficacy of rituximab, a chimeric monoclonal antibody to CD20, in patients with relapsing remitting MS suggested that B cells also play an important role in the pathogenesis of this disease [40] . In actual fact, the presence of oligoclonal IgG bands in the cerebrospinal fluid and deposition of IgG in active lesions have long been known as hallmarks of this disease [3] . Additionally, increasing evidence suggests that macrophages derived from circulating monocytes and resident macroglia play a pivotal role in the pathogenesis of MS [41, 42] . Autopsy specimens from patients with MS revealed macrophages containing myelin debris in active lesions [43] . Whether neuromyelitis optica (also known as Devic's disease), that preferentially affects the optic nerve and spinal cord, is a subtype of MS or an independent disease entity has been a controversy for a long time [44] . The discovery of disease-specific antibodies against AQP4 in the sera from patients with neuromyelitis optica resulted in significant progress regarding this concern [10] . Because AQP4 is expressed in astrocyte foot processes at the blood-brain barrier [45] , pathological findings of AQP4 are characterized by perivascular lesions accompanied by deposition of IgG and complement [12] . Compared with demyelinating lesions found in conventional MS, the myelinated fibers are relatively preserved in these lesions [12] . Based on these findings, neuromyelitis optica is now regarded as a primary astrocytopathy and is distinct from MS. As anti-AQP4 antibodies are found to be associated with not only lesions in the optic nerves and spinal cord, but also those in other sites of the central nervous system, the concept of neuromyelitis optica spectrum disorder (NMOSD) has been proposed [46] . Ultrastructural studies using nerve biopsy specimens obtained from patients with the demyelinating form of GBS (i.e., AIDP) and those with CIDP have demonstrated putative chronological sequence in the progression of demyelination resulting from myelin phagocytosis by macrophages [4, 5] . Generally, the morphology and behavior of macrophages participating in the demyelination process seem to be similar between AIDP and CIDP [4, 5] . Various stages of demyelination may be seen in a single specimen (Figure 1 ), particularly in specimens from patients with CIDP [4] . Although resident macrophages are present in the peripheral nervous system, bloodderived macrophages that enter the endoneurium under the guidance of adhesion molecules, such as ICAM-1, VCAM-1, and ELAM-1, can also participate in the demyelination process [47] [48] [49] [50] . Morphological distinction between these macrophages has not been clearly established despite their functional differences [51] . Macrophages approach the myelinated fibers and extend their cytoplasmic processes to enter the basement membrane tube surrounding the myelinated fibers ( Figure 2 ) [4] . A recent review by Park et al. suggested that the entry sites of macrophages are limited to where myelin lamellae are partially degener-ated or separated from Schwann cell cytoplasm [52] . Along with invading the basement membrane tube, the cytoplasm of macrophages apposed to myelin initiates degradation of the myelin lamellae. Macrophages seem to peel off layers of myelin using their cytoplasmic processes ( Figure 3 ) [4, 5] . Unraveling and disruption of the myelin lamellae apposed to the cytoplasm of macrophages are also frequently observed [4, 5, 53] . Although resident macrophages are present in the peripheral nervous system, blood-derived macrophages that enter the endoneurium under the guidance of adhesion molecules, such as ICAM-1, VCAM-1, and ELAM-1, can also participate in the demyelination process [47] [48] [49] [50] . Morphological distinction between these macrophages has not been clearly established despite their functional differences [51] . Macrophages approach the myelinated fibers and extend their cytoplasmic processes to enter the basement membrane tube surrounding the myelinated fibers ( Figure 2 ) [4] . A recent review by Park et al. suggested that the entry sites of macrophages are limited to where myelin lamellae A cross section of a sural nerve biopsy specimen obtained from a patient with AIDP. A macrophage whose nucleus is indicated by a black asterisk is invading the basement membrane tube that normally surrounds myelinated fibers. Along with the invasion Figure 2 . A macrophage invading the basement membrane tube surrounding the myelinated fiber. A cross section of a sural nerve biopsy specimen obtained from a patient with AIDP. A macrophage whose nucleus is indicated by a black asterisk is invading the basement membrane tube that normally surrounds myelinated fibers. Along with the invasion into the basement membrane tube, the cytoplasm of macrophages apposed to myelin initiates degradation of myelin (white asterisks). Note that the cytoplasm of this macrophage located outside the basement membrane tube does not contain myelin debris. into the basement membrane tube, the cytoplasm of macrophages apposed to myelin initiates degradation of myelin (white asterisks). Note that the cytoplasm of this macrophage located outside the basement membrane tube does not contain myelin debris. A high-powered view of the region in the box in (A) is shown in (B). Basement membranes surrounding myelinated fibers are indicated by arrowheads. Uranyl acetate and lead citrate staining. Scale bars = 2 m (A) and 0.5 m (B). Vesicular dissolution of the myelin has been reported as another important lesion associated with demyelinating diseases, including AIDP and MS ( Figure 4 ) [1, [54] [55] [56] [57] [58] . Most studies describing this finding used autopsy specimens [54] [55] [56] [57] [58] . One of these studies used specimens from patients with AIDP, which demonstrated that the vesicular dissolution occurred where complements were deposited but macrophages were absent [56] . Therefore, this finding might be an early morphological change occurring before a macrophage invasion into the basement membrane tube of the myelinated fibers. However, similar findings also seem to be closely associated with macrophages invading the basement membrane tube ( Figure 5 ) [5, 59] . Therefore, hydrolases released from macrophages may be involved in myelin lesions, including unraveling, disruption, and vesicular dissolution. Vesicular dissolution of the myelin has been reported as another important lesion associated with demyelinating diseases, including AIDP and MS ( Figure 4 ) [1, [54] [55] [56] [57] [58] . Most studies describing this finding used autopsy specimens [54] [55] [56] [57] [58] . One of these studies used specimens from patients with AIDP, which demonstrated that the vesicular dissolution occurred where complements were deposited but macrophages were absent [56] . Therefore, this finding might be an early morphological change occurring before a macrophage invasion into the basement membrane tube of the myelinated fibers. However, similar findings also seem to be closely associated with macrophages invading the basement membrane tube ( Figure 5 ) [5, 59] . Therefore, hydrolases released from macrophages may be involved in myelin lesions, including unraveling, disruption, and vesicular dissolution. Despite these findings resulting in the breakdown of compacted myelin lamellae, the uncompacted Schwann cell cytoplasm located outside the myelin lamellae remains intact [4] . Once the myelin breakdown is completed, macrophages containing myelin debris penetrate the basement membrane again to escape to the outer space ( Figure 6 ) [4, 5] . A similar demyelination process has also been reported in studies of experimental allergic neuritis, which is an experimental model of GBS or CIDP [60, 61] , and experimental allergic encephalomyelitis: a model of MS [62] [63] [64] . Despite these findings resulting in the breakdown of compacted myelin lamellae, the uncompacted Schwann cell cytoplasm located outside the myelin lamellae remains intact [4] . Once the myelin breakdown is completed, macrophages containing myelin debris penetrate the basement membrane again to escape to the outer space ( Figure 6 ) [4, 5] . Note that an axon located within the basement membrane tube is completely demyelinated. A demyelinated axon and a macrophage nucleus are indicated by a black asterisk and a white asterisk, respectively. Uranyl acetate and lead citrate staining. Scale bar = 2 m. A similar demyelination process has also been reported in studies of experimental allergic neuritis, which is an experimental model of GBS or CIDP [60, 61] , and experimental allergic encephalomyelitis: a model of MS [62] [63] [64] . Unlike that on anti-ganglioside GM1 antibodies in AMAN, anti-neurofascin 155 antibodies in nodopathy or paranodopathy, and anti-AQP4 antibodies in NMOSD, knowledge of the relationship between specific autoantibodies and demyelination caused by macrophages is still limited. An association between antibodies against moesin, which is expressed at the microvilli of the Schwann cells at the nodes of Ranvier, and AIDP following cytomegalovirus infection has been suggested [19] . Gliomedin, galactocerebroside, and ganglioside LM1 have also been suggested as target antigens in Figure 6 . A macrophage escaping from the basement membrane tube surrounding the myelinated fiber. A cross section of a sural nerve biopsy specimen obtained from a patient with AIDP. The sites at which the basement membrane was disrupted are indicated by arrowheads. The nucleus of this macrophage is located outside of the basement membrane tube. Note that an axon located within the basement membrane tube is completely demyelinated. A demyelinated axon and a macrophage nucleus are indicated by a black asterisk and a white asterisk, respectively. Uranyl acetate and lead citrate staining. Scale bar = 2 µm. Unlike that on anti-ganglioside GM1 antibodies in AMAN, anti-neurofascin 155 antibodies in nodopathy or paranodopathy, and anti-AQP4 antibodies in NMOSD, knowledge of the relationship between specific autoantibodies and demyelination caused by macrophages is still limited. An association between antibodies against moesin, which is expressed at the microvilli of the Schwann cells at the nodes of Ranvier, and AIDP following cytomegalovirus infection has been suggested [19] . Gliomedin, galactocerebroside, and ganglioside LM1 have also been suggested as target antigens in AIDP [65] [66] [67] [68] . Although recent emerging infectious diseases, including Zika virus infection and COVID-19, are reported to be associated with AIDP rather than AMAN [20, 26] , causative autoantibodies associated with these viruses have not been detected to date. Regarding CIDP, sural nerve biopsy specimens from a patient with antibodies to LM1 ganglioside, which is abundant in myelin, revealed complement deposition on myelin and demyelination by macrophages [69] . However, patients with anti-LM1 antibodies constitute only a minority of the total CIDP population [70] . Recent studies revealed that antibodies to myelin oligodendrocyte glycoprotein (MOG), expressed in the outermost layer of the myelin sheath, were found in some of the patients with NMOSD negative for anti-AQP4 antibodies [71] . The location of the target antigen suggests myelin damage, which is distinct from astrocyte damage in NMOSD positive for anti-AQP4 antibodies [12] . However, patients with conventional MS are typically negative for anti-MOG antibodies [72] . Based on the abovementioned results, the mechanism underlying demyelination, resulting from myelin phagocytosis by macrophages, remains an enigma from the viewpoint of autoantibodies. A recent electron microscopy study using longitudinal sections of biopsy specimens from patients with AIDP suggested that macrophages seemed to select specific sites of myelinated fibers, including the nodes of Ranvier, paranodes, and internodes, for the initiation of demyelination in individual cases [5] . The sites of complement deposition corresponded to the distribution of macrophages in that study, suggesting the presence of undiscovered autoantibodies directed against the components of myelinated fibers in AIDP [5] . The efficacy of eculizumab, a humanized monoclonal antibody to complement component 5, for not only AMAN, but also AIDP, supports this view [73] . Similar selectivity of the sites at which macrophages initiate myelin phagocytosis was also reported in CIDP [4] . However, the pathogenesis of CIDP might be more complex than that of AIDP, considering the heterogeneity of its clinical features and its response to immunotherapies [9] . The mechanisms of demyelination in MS are also considered complex, involving both innate and adoptive (i.e., humoral and cellular) immunities [37, 41] . Additionally, it has been gradually established that macrophages not only contribute to the initiation and development of demyelination by boosting inflammatory events, but they also play a protective role by suppressing inflammation, eliminating debris, and promoting repair [74] . Particularly, immunoregulatory M2 macrophages are considered to be predominant during the recovery and repair process [75] . Further studies focusing on the mechanisms leading to myelin phagocytosis by macrophages are required to elucidate the pathogenesis of demyelinating diseases. Myelin phagocytosis by macrophages has traditionally been considered an essential feature of demyelinating diseases of the central and peripheral nervous systems, including GBS, CIDP, and MS [1] [2] [3] [4] [5] . The discovery of autoantibodies directed against the constituents of the nervous system contributed to the understanding of the disease process in a subpopulation of patients conventionally diagnosed with these diseases. For example, a concept that molecular mimicry between gangliosides located at the axolemma and the surface epitopes of exogenous pathogens induces the production of anti-ganglioside antibodies has been established in the axonal form of GBS, called AMAN [7, 13] . In patients with AMAN, the attachment of autoantibodies to ganglioside GM1 localized to the axolemma of motor fibers and subsequent activation of complement cascades result in the conduction failure of the motor nerve fibers [13, 16, 17] . In a subpopulation of patients with CIDP, autoantibodies against paranodal junction components, including neurofascin 155 and contactin 1, cause aberrant nerve conduction, owing to the detachment of paranodal myelin terminal loops from the axolemma [8] . As demyelinating lesions associated with macrophages are not found in patients with these antibodies, the concept of nodopathy or paranodopathy has recently been proposed [9, 34] . Moreover, NMOSD associated with anti-AQP4 antibodies is now considered a disease entity distinct from MS because astrocytes, rather than oligodendrocytes, are primarily affected [12] . Despite the discovery of these antibodies, the mechanisms underlying demyelination owing to myelin phagocytosis by macrophages remain unclear. Ultrastructural studies revealed that macrophages strip morphologically intact myelin lamellae by their cyto-plasmic processes as if they are principal players in the demyelination process [4, 5] . Unraveling, disruption, and vesicular dissolution of the myelin lamellae are also frequently observed where the cytoplasm of macrophages is present [5] , as if hydrolases released from macrophages may also be involved. Recent electron microscopy studies using longitudinal sections of biopsy specimens from patients with AIDP and those with CIDP suggested that macrophages seemed to select specific sites of myelinated fibers, including the nodes of Ranvier, paranodes, and internodes, for the initiation of demyelination in individual cases [4, 5] . Hence, specific components localized to these sites may play an important role in the behavior of macrophages that initiate myelin phagocytosis. Along with the search for autoantibodies, the ultrastructural characterization of myelin phagocytosis by macrophages is a crucial step in understanding the pathophysiology of demyelinating diseases and for the future development of targeted therapies. The authors declare no conflict of interest. Acute idiopathic polyneuritis. An electron microscope study Chronic inflammatory polyradiculoneuropathy Multiple sclerosis-The plaque and its pathogenesis Ultrastructural mechanisms of macrophageinduced demyelination in CIDP Ultrastructural mechanisms of macrophageinduced demyelination in Guillain-Barré syndrome Chronic relapsing polyneuritis Axonal Guillain-Barré syndrome: Concepts and controversies Paranodal dissection in chronic inflammatory demyelinating polyneuropathy with anti-neurofascin-155 and anti-contactin-1 antibodies Pathophysiology of Chronic Inflammatory Demyelinating Polyneuropathy: Insights into Classification and Therapeutic Strategy IgG marker of optic-spinal multiple sclerosis binds to the aquaporin-4 water channel Guillain-Barré syndrome in northern China: The spectrum of neuropathological changes in clinically defined cases Loss of aquaporin 4 in lesions of Neuromyelitis optica: Distinction from multiple sclerosis Guillain-Barré syndrome An acute axonal form of Guillain-Barré polyneuropathy Axonal pathology in Japanese Guillain-Barré syndrome: A study of 15 autopsied cases Acute motor axonal neuropathy: An antibody-mediated attack on axolemma Anti-GM1 Antibodies Cause Complement-Mediated Disruption of Sodium Channel Clusters in Peripheral Motor Nerve Fibers Guillain-Barré syndrome in a local area in Japan, 2006-2015: An epidemiological and clinical study of 108 patients Moesin is a possible target molecule for cytomegalovirus-related Guillain-Barre syndrome Zika virus infection and Guillain-Barré syndrome: A review focused on clinical and electrophysiological subtypes Guillain-Barré syndrome during the Zika virus outbreak in Northeast Brazil: An observational cohort study Zika virus and autoimmunity: From microcephaly to Guillain-Barré syndrome, and beyond Minimal immune determinants connect Zika virus, human Cytomegalovirus, and Toxoplasma gondiito microcephaly-related human proteins Spanish Investigators in Emergency Situations Team) network. Incidence, clinical, risk factors and outcomes of Guillain-Barré in Covid-19 Epidemiological and cohort study finds no association between COVID-19 and Guillain-Barré syndrome Guillain Barré Syndrome and its variants as a manifestation of COVID-19: A systematic review of case reports and case series Research criteria for diagnosis of chronic inflammatory demyelinating polyneuropathy (CIDP) European Federation of Neurological Societies/Peripheral Nerve Society guideline on management of chronic inflammatory demyelinating polyradiculoneuropathy: Report of a joint task force of the European Federation of Neurological Societies and the Peripheral Nerve Society-First revision Clinicopathological characteristics of subtypes of chronic inflammatory demyelinating polyradiculoneuropathy Illa, I. Antibodies to contactin-1 in chronic inflammatory demyelinating polyneuropathy Destruction of paranodal architecture in inflammatory neuropathy with anti-contactin-1 autoantibodies Characterization of IgG4 anti-neurofascin 155 antibody-positive polyneuropathy IgG4 anti-neurofascin155 antibodies in chronic inflammatory demyelinating polyradiculoneuropathy: Clinical significance and diagnostic utility of a conventional assay Ultrastructural lesions of nodo-paranodopathies in peripheral neuropathies Paranodal lesions in chronic inflammatory demyelinating polyneuropathy associated with anti-Neurofascin 155 antibodies Restoration of a conduction block after the long-term treatment of CIDP with anti-neurofascin 155 antibodies: Follow-up of a case over 23 years Defining the clinical course of multiple sclerosis: The 2013 revisions Immunology of multiple sclerosis B-Cell Depletion with Rituximab in Relapsing-Remitting Multiple Sclerosis Myeloid cells-Targets of medication in multiple sclerosis The physiology of foamy phagocytes in multiple sclerosis Multiple sclerosis: Capping of surface immunoglobulin G on macrophages engaged in myelin breakdown Multiple sclerosis in the Japanese population Molecular characterization of an aquaporin cDNA from brain: Candidate osmoreceptor and regulator of water balance International consensus diagnostic criteria for neuromyelitis optica spectrum disorders Macrophage responses in inflammatory demyelinating neuropathies Serum levels of soluble E-selectin (ELAM-1) in immune-mediated neuropathies The role of the very late antigen-4 and its counterligand vascular cell adhesion molecule-1 in the pathogenesis of experimental autoimmune neuritis of the Lewis rat Soluble intercellular adhesion molecule-I (sICAM-I) in serum and cerebrospinal fluid of demyelinating diseases of the central and peripheral nervous system Competitive repopulation of an empty microglial niche yields functionally distinct subsets of microglia-like cells Behind the pathology of macrophage-associated demyelination in inflammatory neuropathies: Demyelinating Schwann cells Deciphering the mechanism and spectrum of chronic inflammatory demyelinating polyneuropathy using morphology Landry-Guillain-Barré syndrome. A primary demyelinating disease An ultrastructural study of an acute fatal case of the Guillain-Barré syndrome Immune attack on the schwann cell surface in acute inflammatory demyelinating polyneuropathy Fulminant Guillain-Barré syndrome with universal inexcitability of peripheral nerves: A clinicopathological study Demyelination in primate autoimmune encephalomyelitis and acute multiple sclerosis lesions: A case for antigen-specific antibody mediation The role of macrophages in Guillain-Barré syndrome and chronic inflammatory demyelinating polyneuropathy Mechanism of demyelination in experimental allergic neuritis. Electron microscopic studies Zur Feinstruktur der experimentell-allergischen Neuritis beim Kaninchen Electron microscopic studies on ordinary and hyperacute experimental allergic encephalomyelitis Mechanism of demyelination in allergic encephalomyelitis of guinea pigs. An electron microscopic study Chronic relapsing experimental allergic encephalomyelitis: Morphological sequence of myelin degradation Antibodies to acidic glycolipids in Guillain-Barré syndrome and chronic inflammatory demyelinating polyneuropathy Anti-gal-C antibody in autoimmune neuropathies subsequent to mycoplasma infection Antibodies to LM1 and LM1-containing ganglioside complexes in Guillain-Barré syndrome and chronic inflammatory demyelinating polyneuropathy Nodal proteins are target antigens in Guillain-Barré syndrome Complement deposition and macrophage-induced demyelination in CIDP with anti-LM1 antibodies Clinical features of CIDP with LM1-associated antibodies Distinction between MOG antibody-positive and AQP4 antibody-positive NMO spectrum disorders Frequency of myelin oligodendrocyte glycoprotein antibody in multiple sclerosis: A multicenter cross-sectional study Safety and efficacy of eculizumab in Guillain-Barré syndrome: A multicentre, double-blind, randomised phase 2 trial Beneficial or Harmful Role of Macrophages in Guillain-Barré Syndrome and Experimental Autoimmune Neuritis M2 microglia and macrophages drive oligodendrocyte differentiation during CNS remyelination