Ocular neuromyotonia

Ocular Neuromyotonia

Kenneth Ricker (1935–2004) (photo)

Hans Georg Mertens (1921–2006) 

Definition

"intermittent, tonic spasms of one or more of the EOM, resulting in strabismus & paroxysmal diplopia"

-delayed relaxion of EOM makes eye temporarily get 'stuck' after eccentric gaze

- AKA "locking-eye"

Etiology

-MC post-RXT of parasellar area

> 2 monhts to 18 years, mean 5y

-Others: autoimmune disorders (MG & thyroid disease)

-Rare: chemotherapy(cisplatin, 5-FU), Vit B12/D def, thorium myelography, botox injection, alcohol, and cataract surgery

Pathophysiology

-May relate to focal demyelination causing ephaptic transmission

-Eggenberger suggest “reflecting nerve circuit”

-Dysfunction of potassium channels

-Mucopolysaccharide deposition after thyroid-associated orbitopathy

Presentation

-Transient diplopia/strabismus

Neuro-exam

-Prolonged eccentric gaze (1 min)

-Advanced test: electromyography, electrooculography, and videotaping 

Investigation

-bMRI and oMRI w/wo contrast

-TFT

Ddx

-ONM = Triggered by sustained eccentric gaze + brief tonic deviation

-SOM = Torsional micro-oscillations (tremor)

-Cyclic 3rd = Cyclic (predicted) weakness/spasm in a fixed rhythm

-Convergence spasm = Miosis + accommodation

-MG = Fatigues

-Graves = Restrictive pattern + orbital signs

-Decomp phoria = Fatigue‑dependent misalignment without spasm

Therapy

-Carbamazepine & oxcarbazepine

*lower dose

-Others: gabapentin, phenytoin, lacosamide

-Tx hypovitamins

-If refractory, surgery→ binocular fusion w/ strabismus surgery

-Behavioral change, if pt has a AM clock to one side change to other

Videos

ONM

-Nasopharyngeal CA, ttx w/ cisplatin + 5-FU, 9y later transient diplopia

*Worse w/ prolonged eccentric gaze

-Tx CBZ

ONM

-Midbrain glioma, RXT 20y before, now R CN III palsy

-ONM observed during ptosis surgery

ONM

-Full resolution within 1y

-Difficult to atrtibute only to ONM

>Pt does not have tonic spasm

ONM

-Remote hx of pituitary macroadenoma

-Referral for intermittent diplopia for several years

Neurobowl - 2026

Neurobowl - 2026

1️⃣ Video w/ FBDS

A definitive serum diagnostic study was performed. 

Her serum demonstrated _____   ____

LGI-1 antibody

This patient likely has what electrolyte abnormality?

Hyponatremia

2️⃣ Pt w/ clivus chordoma, treated w/ surgery and radiation. 5y later, p/w R CN VI palsy, which was not really palsy was myotonia

Ocular neuromyotonia

-Tx CBZ/OXC

3️⃣ Severe R&L M1 stenosis

This patient's diagnosis is ______ syndrome

-moyamoya

-RNF213 gene

4️⃣ 66yo woman w/ small prior stroke and acute onset dysarthria and dysphagia

-Pseudobulbar palsy

-Foix-Chavany-Marie syndrome

5️⃣ Video w/ stroke pt w/ mouth and genital ulcers

This pt most likely diagnosis is ____

-Behcet

-Cascade sign aka waterfall sign

6️⃣ Hands dark rash, uveitis, and headaches

-VKH (Vogt-Koyanagi-Harada) syndrome

-BEE→ Brain, Ear, Eye

-T-cell autoimmunity targeting melanocytes

7️⃣Video w/ pt closing and having difficult to open hand

She reproted that did not worse with sustained activity

-Myotonia congenita

8️⃣11yo boy w/ abnormal movements occuring when going to the chalkboard 

PKD

-PRRT2

9️⃣This best term for this patient's clinical symptoms is _______

Amusia

"tone-deafness"

Does not recognized tones, you can try happy birthday

1️⃣0️⃣

Brain abscess p/w aphasia

Tongue w/ telangiectasia

Intrapulmonary shunt

Osler Weber Rendu syndrome

Hereditary hemorrhagic telangiectasia

Neurobowl - 2025

Neurobowl - 2025

1 - Stroke, bMRI w/ WMD, skin biopsy w/ lipoma

CADASIL

Notch3

2 - Hemichorea

Subthalamic nucleus (Nucleus of Luys)

3 - JME

EEG: Generalized 4Hz spike-and-wave discharges induced by photic stimulation

4 - Thetered cord

Spinal cord ends around L1/2

5 - West Nile virus

6 - TGA

7 - Frey's syndrome

Cause by parotidectomy

Damage auriculotemporal nerve, which conveys autonomic fibers from the glossopharyngeal nerve

8 - Post-LP headache 2/2 epidural

Pneumocephalus

Intracranial hypotension

9 - Meige syndrome

10 - Peter Brueghel

11 - Melkersson-Rosenthal syndrome

-Lingua plicata 

12 - Pseudogout

Rhomboid-shaped crystals

Polarized light

13 - I-CAA

Inflammatory-CAA

14 - Vogt Koyangi Harada disease

T-cell-mediated autoimmunity targeting melanocytes

15 -  

Neurobowl - 2024

Neurobowl - 2024

1. Silas Weir Mitchell

-Discoverer of the phantom limb

2. ⁠Right sciatic nerve causing a foot drop

3. Left dorsal pons

4. 8 and a half syndrome
1 + 1/2 + CN 7 = 8 and 1/2

5. Nitrous oxide leading to a myelopathy

6. Dural AV fistula

7. DYT1 Dystonia, not dopamine responsive 
-TorsinA

-Showing a child w/ leg involvement, and significant improvement after DBS

8. Cheiro oral syndrome

9. X linked adrenoleukodystrophy

-accumulation of VLCFAs

-defect ABCD1→ impair peroxisomal β‑oxidation→ VLCFAs accumulate

10. Myokymia and 11. Radiation plexitis

- lung cancer w/ radiation 8y before

- now brachial plexus distribution myokymia

12. ALS with Stephen Hawking

13. Locked in syndrome

Movie: The Diving Bell and the Butterfly

14. Marginal mandibular branch of the facial nerve injured during surgery

15. Eastchester Clapping Sign

-Hemispatial neglect

-Eastchester High School

16. Dermoid cyst

Epidermoid cyst→ Restricts on diffusion; not T1-bright

Lipoma→ Pure fat, usually no calcifications or heterogeneous contents

Arachnoid cyst→ CSF intensity across all sequences, no fat

Teratoma→ Contains fat + soft tissue + calcifications; more complex

17. Facioscalpohumeral dystrophy and 

18. beevor sign

“movement of umbilicus in supine attempting to flex the head”

19. Post fixational blindness in bitemporal hemianopia

Kahoot

Kahoot!

Profile

https://create.kahoot.it/profiles/14f1aff3-80fe-4d6d-8a48-a032d5620f2e

Content

-Anatomical syndromes

-QoD

AIS Guideline 2018-2026

AIS Guideline 2018-2026

What Really Changed?

Based on Prabhakaran et al. (2026)

2026 Guideline for the Early Management of Patients With Acute Ischemic Stroke: A Guideline From the American Heart Association/American Stroke Association

IVT

Thrombolytic Agent

2018: Alteplase only (standard 0.9 mg/kg)

2026: Tenecteplase (0.25 mg/kg) or alteplase — both Class I recommended

*Tenecteplase 1st-line, if LVO bridging therapy, patients requiring rapid workflow, difficult IV access or prehospital administration

NIHSS and Disability

2018: NIHSS severity emphasized

2026: Any disabling deficit should receive IVT — NIHSS alone should not delay therapy

Ex: aphasia, hemianopia, dominant-hand weakness

Non-disabling stroke

2026: IVT not recommended; DAPT preferred

Extended Window

2018: Mainly MRI DWI–FLAIR mismatch (“wake‑up stroke”)

2026: Perfusion-based IVT up to 9 hours, including wake-up/unknown onset strokes

-CTP

-bMRI D/H: DWI lesion involving <1/3 of MCA territory with no FLAIR signal changes

Contraindication

-prior ICH, DOAC exposure, and stroke within the past 3-months are now relative contraindications

sICH after IVT

EVT

Time Window

2018: 0–6 hrs standard; 6–24 hrs selective (DAWN/DEFUSE‑3)

2026: 0–24 hrs broadly accepted with imaging selection

Large Core Infarcts

2018: Mostly excluded

2026: ASPECTS 3–5 recommended; even 0–2 reasonable in select cases (Class IIb)

>Supported by RESCUE‑Japan, SELECT2, ANGEL‑ASPECT data

Posterior Circulation

2018: No strong recommendation

2026: Class I recommendation for basilar artery thrombectomy (≤24 hrs)

>Supported by ATTENTION & BAOCHE

Pre-stroke Disability

2026: mRS 2 patients now included

Pediatric EVT (NEW)

≥6 years: Class IIa

<6 years: Class IIb selected cases

First formal pediatric interventional guidance

Pediatric AIS

Imaging

-MRI/MRA preferred, but if MRI cannot be obtained within 25 minutes, use CT/CTA to evaluate for LVO

Treatment

-IV alteplase: May be safe, but efficacy remains unclear

-EVT in pediatric LVO (see above)

Early BMT

Glycoprotein IIb/IIIa inhibitors

-No established benefit for IV tirofiban

-IV abciximab is discouraged

Oral anticoagulation

-Early initiation reasonable for mild strokes with Afib

Post‑EVT BP management

-Avoid intensive SBP <140 immediately after thrombectomy

DAPT

-Now recommended for patients presenting within 72h, NIHSS ≤5, and suspected atherosclerotic disease

https://live.avomd.io/algo/01542d1291e749fca1

Remaining gaps

-EVT for NIHSS ≤6

-Optimal intra‑arterial thrombolysis dosing

EEG - Delta wave

Delta Wave

Denition

-Frequency: <4 Hz

-Physiology: Large‑amplitude, slow oscillatory activity

Mechanism

-2 major neuronal generators:

>Thalamocortical networks→ synchronous, rhythmic delta (particularly in sleep)

>Intrinsic cortical circuits→ focal, polymorphic delta (often pathological)

-Modulators:

>Glial/astrocytic networks influence slow oscillations

*Delta is never generated by purely neuronal mechanisms

Interpretation 

-Depends age, vigilance state, topographic distribution, morphology, reactivity, and clinical context

Age

-Infancy: abundant delta→ physiologic

  ~10 years: <10% of background

-Adults: largely absent in awake state

-Elderly: up to ~1% may persist as physiologic

State

-Delta↑ w/ ↓alertness

>Drowsiness: ↑, often temporal

-Hyperventilation: ↑ generalized delta

-N3 sleep: high‑amplitude, synchronous, generalized delta (“slow‑wave sleep”)

Topography and morphology

-Polymorphic focal delta

>Persistent, non‑reactive, state‑independent→ strong marker of structural lesion (subcortical lesions or large cortical lesions)

-Generalized polymorphic delta

>Suggests diffuse encephalopathy

Rhythmic patterns

-FIRDA (Frontal Intermittent Rhythmic Delta Activity)

>Bilateral, symmetric, intermittent rhythmic delta

>Associated w/ diffuse cerebral dysfunction, ↑ICP, or metabolic encephalopathy

>Benign in children/teens

-TIRDA (Temporal Intermittent Rhythmic Delta Activity)

>Focal, typically unilateral

>Associated w/ TLE, even w/o interictal spikes

-OIRDA (Occipital Intermittent Rhythmic Delta Activity)

>Mainly in children

>Associated w/ CAE and others idiopathic generalized epilepsies

-LRDA (Lateralized Rhythmic Delta Activity)

>Critically ill patients

>IIC pattern

-GRDA  (Generalized Rhythmic Delta Activity)

>Seen in: encephalopaty, sedation,  post‑anoxic injury

>Not epileptiform unless evolving

-SIRPIDs  (Stimulus‑Induced Rhythmic, Periodic, or Ictal‑appearing Discharges)

>Often rhythmic delta following stimulation

>Occur in comatose, septic, or anoxic patients

>Falls under IIC spectrum

-Delta brush pattern

>Fast activity riding on delta

-Seen in: Anti‑NMDA encephalitis (extreme delta brush), premature neonates (physiologic delta brush)

Clinical significance

-Excess generalized delta→ diffuse encephalopathy

-Focal persistent delta→ structural pathology

-Intermittent rhythmic delta→ epilepsy or prior brain injury (location matters)

>Temporal→ TLE

>Occipital→ CAE

>Frontal→ diffuse dysfx

Clinical pearl

-Delta alone is never inherently normal or abnormal — context determines meaning

-Persistent focal polymorphic delta has the highest specificity for structural lesions

-Rhythmic delta is more associated with epilepsy or IIC than polymorphic delta

-Non‑reactive generalized delta in an awake adult→ think encephalopathy

Nodo‑Paranodopathy

Nodo‑Paranodopathy

"My AIN, PAIN"

History

1990s Anti-GM1, paradox of electrical demyelination w/ axonal integrity

2012-2013 Uncini & Kuwabara, term nodopathy

2021 EAN guidelines AIN≠CIPD

Pathophysiology

-AIDP/CIDP = macrophage btw myelin lamellae→ T‑cell recruitment→ segmental demyelination

>Schwann cells shift into iDSc (mimicry)

>AKA macrophage‑associated demyelinating (MAD)-neuropathy

>Demyelination = temporal dispersion + conduction block caused by segmental myelin loss

-NP = Ab-mediated

>Start paranodal loops

>AKA pure antibody‑induced neuropathy (AIN-PAIN)

>Reversible conduction failure (RCF)

  RCF = nodal dysfunction w/o structural injury

Localization

-Node (Kv7)

>NF‑186 (often severe and fulminant)

-Paranode

>NF‑155 (classically tremulous phenotype)

  Triad: Young + ataxic + tremulous

  

>CASPR1

>Contactin‑1 (CNTN‑1) (classically edematous phenotype)

  Triad: Elderly + aggressive + edematous

  Assoc w/ membranous glomerulopathy

-Juxtaparanode (Kv1)

>CASPR‑2

>LGI4

PAIN

-2 types = ganglioside & nodal

Ganglioside Ab

-Usually transient

-Typically produce AIDP presentations

-Often reversible

Nodal Ab

-AIDP/CIDP-like

- AIDP-like: RFC; if early, complete recovery

>Severe cases (like IgG3) activate MAC; irreversible

Acute vs. Chronic

-concept  of IgG class switch

Acute Phase

-Driven by short‑lived plasmablasts

-IgG3 Ab→ ⊕complement (fulminant damage)

Chronic Phase

-Maintained by long‑lived plasma cells

-switch to IgG4 Ab→ ⊖complement; act as functional blockers

*smoldering neuropathy

Therapy

Seropositivity matters for treatment choice

-RTX→ effective IgG4 disorders

-IVIG→ less effective in IgG4

>IVIG relies on complement inh

Consider Ab-test if:

-tremor, ataxia, speed (aggressive), resistance (IVIG), comorbidies (GN), pain

Summary

-First-line

>RTX for NF155, CNTN1, CASPR1 (IgG4/IgG3)

>IVIG/PLEX for ganglioside-mediated AIN, CASPR2

-Second-line

>Combination RTX + IVIG for overlap or refractory cases

Epileptiform Discharge

Epileptiform Discharge

According to IFCN, a waveform can be considered epileptiform if ≥4 of 6 defining features are present:

1️⃣ Physiological field of distribution

-The discharge must have a plausible neurophysiological field.

-It should show:

>A clear phase reversal

>A logical spatial voltage gradient

>Distribution consistent with cortical generators

This helps differentiate true cortical discharges from artifact or benign variants

2️⃣ Morphology: spike or sharp wave

-The waveform must have the morphology of:

>Spike: duration < 70 ms

>Sharp wave: duration 70–200 ms

These reflect synchronous neuronal depolarization

3️⃣ Asymmetry of the waveform

-The ascending limb is steeper and more vertical

-The descending limb is slower and less steep

This asymmetry distinguishes epileptiform discharges from benign rhythmic activity

4️⃣ After-Coming Slow Wave

-A true epileptiform discharge is often followed by a slow wave

-This represents:

>Spike → depolarization

>Slow wave → inhibitory postsynaptic potentials/repolarization

The slow wave reinforces epileptogenic significance

5️⃣ Duration Different from Background

-The waveform should have a clearly different duration from surrounding background rhythms

-It should stand out from alpha, theta, or delta activity

This ensures it is not a fragment of background oscillation

6️⃣ Disruption of Background Activity

-The discharge should interrupt or distort ongoing background rhythms

-There may be:

>Transient attenuation

>Phase resetting

>Background interruption

This indicates abnormal cortical synchronization

Locked-In Syndrome

Locked-In Syndrome

SPT

Communicationg strategies

Low‑Tech AAC

-Early on during acute and subacute rehab

 If look to all directions→ transparent board

 If only up/down→ technique (go by line, and then letter)

>Eye‑blink systems (1 blink = yes, 2 = no)

>Eye-gaze boards (alphabet boards, color-coded grids)

>Partner-assisted scanning

>Simple speech-generating switches, if any movement available (e.g., toe, finger, head, eyelid)

High‑Tech AAC

-Stable eye movement or small residual motor control

>Eye-tracking communication devices (e.g., Tobii Dynavox, EyeLink)

>Brain–Computer Interface (BCI) systems (experimental but promising)

>Speech-generating AAC tablets