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Vol. 37. Issue 8.
Pages 700-702 (October 2022)
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Vol. 37. Issue 8.
Pages 700-702 (October 2022)
Letter to the Editor
Open Access
Positive anti-GQ1b Miller Fisher syndrome and Escherichia coli infection: A case report
Síndrome de Miller Fisher anti-GQ1b positivo e infección por Escherichia coli: reporte de un caso
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J.H. Bejarano-Ferreyraa, W. Aguirre-Quispea,
Corresponding author
Wilfor.aguirre.q@upch.pe

Corresponding author.
, E. Guevara-Silvab, L. Torres-Ramírezc, M. Flores-Mendozac
a Instituto Nacional de Ciencias Neurológicas, Lima, Peru
b Centro Básico de Investigación en Demencia y Enfermedades Desmielinizantes del Sistema Nervioso, Instituto Nacional de Ciencias Neurológicas, Lima, Peru
c Centro de Investigación de Enfermedades Neurodegenerativas, Instituto Nacional de Ciencias Neurológicas, Lima, Peru
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A 56-year-old man without significant pathological history came to our emergency room in November 2019 with a 9-day history of sudden onset diplopia associated with nausea and vomiting, hands and feet numbness, one day later instability to walk was added, increasing in the following three days, making impossible to stand. Three days later, the patient manifested moderate occipital headache that remitted partially with analgesics. Three weeks before admission, the patient presented with a self-limited episode of nonbloody diarrhea. At admission, the patient had normal vital functions. The general examination was not contributory. In the neurological exam, strength and tone was preserved, osteotendinous reflexes was abolished, superficial cutaneous reflexes were normal with bilateral flexor plantar response, hypoesthesia in the distal region of the four extremities with normal deep sensitivity. Instability for standing, ataxic gait with a widening of the base of support, and inability to perform tandem gait was evidenced, while limb coordination was preserved. Bilateral oculomotor, trochlear, and abducens nerves were compromised. No meningeal signs or abnormal movements was found. Necessary blood tests (hemogram, glucose, urea, creatinine, electrolytes, and liver profile) showed no alterations. The serological tests for Human Immunodeficiency Virus and Syphilis were non-reactive, vitamin B12 (609pg/ml), and folic acid (14.8ng/ml) was normal, as the thyroid profile (TSH 2150u/ml, T4 5.7IU/dl T3 82IU/dl). Brain MRI showed no abnormalities. Cerebrospinal fluid was characterized by 4 WBC, glucose 69mg/dl, and protein elevated to 66mg/dl; no germs was found in the Gram stain or in India ink stain. On the other hand, the nerve conduction study showed acute axonal sensory polyneuropathy that affected all four extremities (Table 1). IgG and IgM titers for Zika, Chikungunya, and Dengue viruses was not detected, while Escherichia coli (E. coli) was isolated in routine stool cultures. Finally, serum anti-ganglioside GQ1b antibody was positive (1:12,800). The patient received symptomatic treatment and physical therapy only, regaining gait stability and complete ocular motility 15 days after discharge because of progressive improvement in hospitalization.

Table 1.

Sensory and motor nerve conduction study.

Sensory NCS
Nerve/site  Latency(ms)  Peak Ampl(μV)  Distance(cm)  Velocity(m/s) 
Right median
Wrist  12 
Left median
Wrist  12 
Right ulnar
Wrist  2.10  15.2  12  57.1 
Left sural
Calf/Lat malleolus  2.45  5.5  14  57.1 
Right sural
Calf/Lat malleolus  2.65  6.5  14  52.8 
Motor NCS
Nerve/site  Latency(ms)  Peak Ampl(mV)  Distance(cm)  Velocity(m/s) 
Right median
Wrist  4.05  10.4  21  60.9 
Elbow  7.50  9.9     
Left median
Wrist  4.05  5.3  21  51.2 
Elbow  8.15  5.3     
Right ulnar
Wrist  2.65  8.7  22  52.4 
Elbow  6.85  7.6     
Right comm peroneal
Ankle  3.75  8.7  30  48.8 
Fib head  9.90  7.0     
Left comm peroneal
Ankle  4.20  7.3  32  49.6 
Fib head  10.65  6.3     
Left tibial (knee)
Ankle  4.65  9.0  37  43.5 
knee  13.15  8.9     
Discussion

Miller Fisher syndrome (SMF) is an acute immune-mediated neuropathy characterized by the clinical triad of ophthalmoplegia, ataxia, and areflexia.1 Although it was first described in 1932 by James Collier, it has been considered a variant of Guillain Barré Syndrome (GBS) since 1956, when Charles Miller Fisher reported three cases with similar findings cerebrospinal fluid.2

SMF represents about 5% of Guillain Barré Syndrome cases; however, in eastern populations such as Japan, the incidence reaches 25%, being more frequent in men with a 2:1 ratio.3 It manifests with diplopia due to paralysis of oculomotor nerves, ataxia due to compromise of sensory roots in the peripheral nervous system, which also explains distal dysesthesias and hypo-areflexia. The involvement of bulbar nerves has been reported less frequently. A study that analyzed the characteristics of patients with Miller Fisher syndrome found 88% seropositive patients for antibodies against GQ1b ganglioside, however, within the seronegative group the IgG antibodies presence against GM1b, GD1c, GalNAc-GM1b and gangliosides complexes have been described.4 Since the pathogenic mechanisms have not been experimentally demonstrated in humans, hypotheses are still being raised about MFS development. The most accepted theory is “molecular mimicry”, which suggests the structural carbohydrates of these microorganisms’ “mimics” components of nerve cells, called gangliosides, containing sialic acid and form part of neuronal membranes.5 Immunofluorescence studies showed the expression of ganglioside GQ1b in the paranodal myelin of the extramedullary portion of cranial nerves that innervate the extraocular musculature, dorsal root ganglion cells, and muscle spindles so that the antibodies created against some microorganisms cause a cross-reaction against the ganglioside, destroying it and affecting the paranodal region of the myelin sheath.6 Our patient presented the classic triad of ophthalmoplegia, ataxia, and areflexia; however, it corresponds to a case of atypical MFS due to the overlap with GBS, demonstrated by electromyography, which represents 17% of MFS cases, there may also be ophthalmoplegia without ataxia and ataxic neuropathy without ophthalmoplegia.7 On the other hand, the albumin-cytological dissociation found in this report has been described in 41% of patients with SMF.8 The favorable evolution without immunomodulatory treatment coincides with the literature. It is known that the prognosis of patients with MFS at 6 months is good (Hughes Functional Grading Scale1), even without treatment, mainly because they don’t have respiratory compromise.9,10 Various infectious agents are known to cause the immunopathogenic mechanism associated with MFS. The most frequent is Campylobacter jejuni, followed by Haemophilus influenzae,11Epstein-Barr virus, Cytomegalovirus, Streptococcus pyogenes,12Mycoplasma pneumoniae, and Salmonella enteritidis.13 Only one MFS case that developed one month after E. coli pyelonephritis was reported until now, and the anti-ganglioside GQ1b antibody was not detected.14 Moreover, E. coli is associated with the axonal variant of GBS15 and recurrence of this disease,16 the importance of searching for this pathogen.

Conclusion

Therefore, we report for the first time in the literature a case of MFS associated with E. coli with the demonstration of anti-GQ1b serum antibody, with favorable evolution despite no immunomodulatory treatment.

References
[1]
S. Bukhari, J. Taboada.
A case of miller fisher syndrome and literature review.
[2]
M. Fisher.
An unusual variant of acute idiopathic polyneuritis (syndrome of ophthalmoplegia, ataxia and areflexia).
N Engl J Med, 255 (1956), pp. 57-65
[3]
M. Mori, S. Kuwabara, T. Fukutake, N. Yuki, T. Hattori.
Clinical features and prognosis of Miller Fisher syndrome.
Neurology, 56 (2001), pp. 1104-1106
[4]
M. Koga, M. Gilbert, M. Takahashi, J. Li, K. Hirata, T. Kanda, et al.
GQ1b-seronegative Fisher syndrome: clinical features and new serological markers.
J Neurol, 259 (2012), pp. 1366-1374
[5]
N. Yuki.
Ganglioside mimicry and peripheral nerve disease.
Muscle Nerve, 35 (2007), pp. 691-711
[6]
A. Chiba, S. Kusunoki, H. Obata, R. Machinami, I. Kanazawa.
Ganglioside composition of the human cranial nerves, with special reference to pathophysiology of Miller Fisher syndrome.
Brain Res, 745 (1997), pp. 32-36
[7]
Y. Fukami, A.H. Wong, K. Funakoshi, A.Y. Safri, N. Shahrizaila, N. Yuki.
Anti-GQ1b antibody syndrome: anti-ganglioside complex reactivity determines clinical spectrum.
Eur J Neurol, 23 (2016), pp. 320-326
[8]
A.H.Y. Wong, T. Umapathi, Y. Nishimoto, Y.Z. Wang, Y.C. Chan, N. Yuki.
Cytoalbuminologic dissociation in Asian patients with Guillain-Barré and Miller Fisher syndromes.
J Peripher Nerv Syst, 20 (2015), pp. 47-51
[9]
Y. Zhang, Y. Zhao, Y. Wang.
Prognostic factors of Guillain-Barré syndrome: a 111-case retrospective review.
Chin Neurosurg J, 4 (2018), pp. 14
[10]
H.X. Bai, Z.L. Wang, L.M. Tan, B. Xiao, J.M. Goldstein, L. Yang.
The effectiveness of immunomodulating treatment on Miller Fisher syndrome: a retrospective analysis of 65 Chinese patients.
J Peripher Nerv Syst, 18 (2013), pp. 195-196
[11]
M. Mori, S. Kuwabara, M. Miyake, M. Noda, H. Kuroki, H. Kanno, et al.
Haemophilus influenzae infection and Guillain–Barré syndrome.
Brain, 123 (2000), pp. 2171-2178
[12]
M. Odaka, N. Yuki, K. Hirata.
Anti-GQ1b IgG antibody syndrome: clinical and immunological range.
J Neurol Neurosurg Psychiatry, 70 (2001), pp. 50-55
[13]
J.J. Rodríguez Uranga, F. Delgado López, E. Franco Macías, M.B. Sánchez Arjona, C. Martínez Quesada, A. Palomino García.
Síndrome de Miller-Fisher: hallazgos clínicos, infecciones asociadas y evolución en 8 pacientes.
Med Clin (Barc), 122 (2004), pp. 223-226
[14]
A. Blasetti, M. Cerruto, R. Cutarella, A. Tocco, M.C. Caporale, F. Chiarelli, et al.
Miller Fisher syndrome and Escherichia coli infection: is it a novel association?.
J Child Neurol, 22 (2007), pp. 71-73
[15]
Y. Kono, K. Nishitarumizu, T. Higashi, K. Funakoshi, M. Odaka.
Rapidly progressive Guillain-Barré syndrome following Escherichia coli infection.
Intern Med, 46 (2007), pp. 589-591
[16]
Y.S. Jo, J.Y. Choi, H. Chung, Y. Kim, S.J. Na.
Recurrent Guillain-Barré syndrome following urinary tract infection by Escherichia coli.
Copyright © 2021. Sociedad Española de Neurología
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