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

Aortic Arch - Anatomy

Aortic Arch - Anatomy

Variants

-Subclavian

>Aberrant R subclavian

>Aberrant R subclavian + carotid vert origin

>Vert origin from supreme intercostal

>R-side arch, L-sided heart

-Arch

>Classic

>Bovine

>Direct Vert 1

>Direct Vert 2

229. Accepted

228. Accepted

Stroke - Anticoagulation

Stroke - Anticoagulation

Coagulation cascade

DOAC

Direct factor Xa inhibitor

-prevent thrombin formation

>Apixaban (Eliquis)

>Rivaroxaban (Xarelto)

>Edoxaban (Lixiana)

>Betrixaban (Bevyxxa)

Direct thrombin inhibitor

>Dabigatran (Pradaxa)

VKA

-Warfarin (Coumadin)→ deplet CS 1972

>Vit K-dependent clotting factors (protein C, protein S, X, IX, VII, II)

Heparin

-Factor Xa inhibitor

UFH

-IV Hep

LMWH

-Enoxaparin (Lvenox), Dalteparin (Fragmin), Tinzaparin (Innohep)

Fondaparinux

(Arixtra)

-IV, if HIT

Parenteral direct thrombin inhibitor

-Argatroban

-Bivalirudin

Consider in stroke

Afib→ DOAC

Mechanical valve stroke→ warfarin

CVST→ heparin transition DOAC/warfarin

Cancer-assocaited stroke→ LMWH or DOAC

APS-related stroke→ warfarin

Reversal agents

Andexanet alfa

>Only given if NSGY indication

TNK

- Cryoprecipitate to replenish fibrinogen

- Tranexamic acid or aminocaproic acid can be administered to prevent further fibrinolysis

Stroke - Dissection

Dissection

Difference IC vs EC

-IMA = Intima, Media, Adventitia

*external elastic lamina

Traumatic vs non-traumatic

-If blunt, full AC (heparin preferred) according to trauma guidelines

Non-traumatic

-If EC: ASA vs DAP vs AC = same benefit

-If IC: no data

Observations

-wait 1y for pregnancy

MS - Diagnosis

Multiple Sclerosis - Diagnosis

"Multiple Sclerosis," 1955

Douglas McAlpine (1890–1981)

Nigel Compston (1918–1986)

Charles Lumsden (1913–1974)

History - dx criteria

-Allison and Millar 1954

-McAlpine 1957, 1965

-Schumacher 1965

-McDonald and Halliday 1977

-Poser 1983

-McDonald (International) criteria 2001, 2005, 2010, 2017, 2024

Considerations

-MS remains dx of exclusion

-20% misdx

-MS dx→ DIS + biological ± DIT (optional)

Questions

Q1 Does the patient have a syndrome compatible with MS?

Q2 Is there any better explanation?

Q3 Does the patient meet DIS?

Q4 Is there biological evidence supporting MS?

Q1 Compatible presentation?

-ON

-TM

-Brainstem syndrome

-Cerebellar syndrome

-Classic CIS

-Progressive

-Incidental lesions

Q2 Better explanation?

-Migraine

>Tiny T2 lesion

-Vascular disease

>MVD: HTN, DM, smoking

-NMOSD, MOGAD

-Spinal dural AVF

-Metabolic or infectious myelopathies

Q3 DIS?

Definition

≥1 T2 lesion in ≥2 of the 5 locations

PISCO

Periventricular, Infratentorial, Spinal cord, Cortical/juxtacortical, Optic nerve

How to confirm ON

-OCT: ≥6 µm pRNFL difference or ≥4 µm GCIPL difference

-VEP: P100 latency prolongation

-MRI: intrinsic ON lesions, w/o chiasmal/perineuritis features

Q4 Biological evidence or DIT?

DIT

-Not req

>substituted by DIS + paraclinical markers

-Definition

>New T2 lesion

>New Gd+ lesion

>Simultaneous Gd+ and non‑enhancing lesions

Biological evidence

-CSF Markers

>OCBs

>kFLC

-MRI Markers

>CVS

>PRLS

Reverse algorithm

OBSERVATIONS

RIS/CIS to MS

-RIS at 10y→ 50-51%

-CIS at 20y→ 60-70%

Higher-misdx-risk

≥50 yo individuals 

-Should have bMRI and more 1 of below

>Spinal cord lesion

>Select‑6 CVS

>Positive CSF marker

Unified framework

Relapsing MS→ RRMS; Progressive MS→ PPMS or SPMS

-RRMS→ Clinical relapse or DIT + DIS (or CSF OCB/kFLC)

-PPMS→ 1 year progression + DIS + CSF OCB/kFLC

-SPMS→ Relapsing MS + progression

Investigation

OCB-CSF

≥2 OCBs in CSF that are NOT in serum = POSITIVE

-Think: “2 = MS”

kFLC

-High kFLC index = intrathecal IgG production = MS‑supportive

-kFLC index ≥6.1 = positive (supports MS)

CVS

-MS lesion = vein in the middle

≠mimics: migraine or MVD

-SELECT-6: ≥6 lesions, and at least 6 of them show a CVS

>Use susceptibility-based imaging (2/2 inside vein deoxyHb)

  SWI (prefer clinical), T2* EPI (research) FLAIR* (FLAIR combined with T2*/SWI)

  Look for a dark vein running through the lesion center

TIP: 3D FLAIR (s/f lesion), switch SWI (is CVS?), switch FLAIR* to confirm; lesion in 2-planes

PRLS

-Iron-ring lesions = chronic active MS lesions

>Iron‑laden microglia

-Criteria: ≥1 PRL lesion (SP99.7%)

*≥4 PRLS associated w/ ↑ disability (research)

>Use susceptibility-based imaging

  SWI (prefer), T2*

  Look for dark paramagnetic rim around a FLAIR-bright lesion

TIP: FLAIR (s/f lesion), switch to SWI, exclude other causes (CVS, hemosiderin from trauma, MCB, calcification); s/f periventricular first; lesion in 2-planes

ESUS

ESUS (Embolic Stroke of Undetermined Source)

Definition

1st description 2014

-Specific subset of cryptogenic stroke

>No major CE factors

  >Embolic Stroke of Undetermined Source

    >17% of IS

Diagnostic

Basic

-bMRI & vessel (CTA/ MRA)

Advanced

Vascular

-Vessel wall MRI (black-blood sequence)

>Eval of high-risk A-A, although no significant stenosis

-T1-fat suppression

>if c/f dissection

-DSA

>highly c/f vasculitis

Cardiac

≠TTE, TEE, Cardiac CT, and Cardiac MRI

If PFO→ LE and UE dopplers; pelvic MR venography

-TCD-HIT

Rhythm monitoring

MCOT/ ILR

Labs

Hypercogulable panel

>repeat in 3mo for confirmation

Autommine work-up

Others

CAP CT scan w/ IV contrast

PET CT scan

Age-appropriate cancer screening, fu w/ PCP

>CEA

>CA19-9

Therapy

-ASA

>DOAC not superior to ASA

  >NAVIGATE ESUS and RE-SPECT ESUS

DBS - Intro

DBS Programming - Intro

Neurophys

-DBS activate axons

-DBS ↓excessive synchronization in motor network

-DBS activates multiple populations

Parts

-Brain electrode

-IPG/Battery

-Patient programmer

-Clinician programmer

Brain electrodes

Medtronic

-3389 ring (0.5mm spacing)

-3387 ring (1.5mm spacing)

-Segmented (Sensight), 0.5 or 1.5mm spacing

Abbott (formerly St. Jude)

-Segmented, 0.5 or 1.5mm spacing

Boston Scientific

-8 ring contacts

-Segmented 8 contact (Cartesia)

-Segmented 16 contacts (Cartesia X & HX)

-all 0.5mm spacing

IPG

Medtronic

-Activa

>PC (primary cell, dual channel)

>SC (primary cell, single channel)

>RC (rechargeable, dual channel)

-Percept PC (primary cell, dual channel, sensing)

-Percept RC (rechargeable, dual channel, sensing)

Abbott

-Infinity 5 (primary cell, dual channel, small)

-Infinity 7 (primary cell, dual channel, large)

-Liberta RC (rechargeable, dual channel)

Boston Scientific

-Vercise (rechargeable, dual channel)

-Vercise Gevia (rechargeable, dual channel, wand)

-Vercise Genus R16 or P32 (rechargeable, 2-4 leads, Bluetooth)

-Vercise Genus P16 or P32 (primary cell, 2-4 leads, Bluetooth)

Clinician programmer

-Medtronic tablet (Samsung)

-Abbott tablet (iPad)

-Boston Scientific tablet (Surface)

Patient programmer

-Medtronic (Samsung smartphone or remote)

-Abbott (iPad mini)

-Boston Scientific (remote; Gevia-gray; Genus-black)

Adjustable parameters

-Amplitude (2-3 mA or V)

>Spread of stimulation

-Pulse width (60-90 μs)

>Time linger in tissue

-Frequency (130-180 Hz)

>Least important

>↑Hz (180)→ tremor; ↓Hz→ gait

Nomenclature

General

-Leads vs Electrodes vs Contact

-Negative contact = cathode

>active contact; most neural activation

-Positive contact = anode

>current return; some neural activation

-Contact labelling

-Therapy impedance and current

Medtronic Percept

Ring

>0–3(L); 8–11(R)

Segmented

>0, 1A, 1B, 1C, 2A, 2B, 2C, 3

>8, 9A, 9B, 9C, 10A, 10B, 10C, 11

*Segments labeled counter-clockwise

 L brain: A (ant), B (lat), C (med)

 R brain: A (ant), B (med), C (lat)

*Multiple current source, so each contact assigned its own amplitude

Abbott

-U/L: 1, 2A, 2B, 2C, 3A, 3B, 3C, 4

-R: 9, 10A, 10B, 10C, 11A, 11B, 11C, 12

*Segment A usually implanted anterior (but can rotate)

*Segments labeled clockwise

 L brain: A (ant), B (med), C (lat) 

 R brain: A (ant), B (lat), C (med)

*Single current source, so one amplitude split between contacts

Boston Scientific

Ring

>U/L: 1–8

>R: 1–8 (old 9–16)

Segmented

>L: 1, 2A, 2B, 2C, 3A, 3B, 3C, 4 (previously 1, 2/3/4, 5/6/7, 8)

>R: same as Left (previously 9, 10/11/12, 13/14/15, 16)

*Segments labeled counter-clockwise

 L brain: A (ant), B (lat), C (med)

 R brain: A (ant), B (med), C (lat)

*Multiple current source, so each contact assigned its own amplitude

Segment leads - orientation

-Stereotactic marker for determining orientation of segments

-Leads typically implanted with segment A facing anterior

>Medtronic: proximal marker (triangle down) aligned with segment A; distal marker (triangle up) aligned with B

>Boston, Abbot: vertical marker aligned with segment A

-Repeat X-ray or CT for orientation

Contact configuration

-monopolar, double monopolar, fractionated monopolar, wide bipolar, narrow bipolar, double bipolar

First Programming

-2-4wks after procedure 2/2 micro-lesioning effect

-For PD, hold meds

-Check surgical sites

-Monopolar mapping

>Explain side effects

>Choose 130hz and 60us, adjust amplitude

>Amplitude jumps 0.5 if paresthesias 0.1

>Neuro-exam, including speechs for every change in amplitude

Side effect map

Vim

-Muscle contraction→ Lat

-Dysarthria→ Lat/Posteromedial

-Paresthesia→ Post

-Ataxia→ Ventral

-No side effect >5mA→ Sup/Ant

STN

-Paresthesia→ Medial/Post

-Muscle contraction→ Lat/Ant

-Dysarthria→ Lat/Ant

-Mood→ Inf/Med

-Autonomic→ no specific region

>Diplopia→ anteromedial

-Dyskinesia→ at the site!

-No side effect >5mA→ Sup/Ant

GPi

-Muscle contractions→ PostMed

-Dysarthria→ PostMed

-Phosphenes→ DeepMed

-Dyskinesia→ at the site!

-Bradykinesia→ Med

-FOG→ Med

-No side effect >5mA→ Ant/Lat/Dorsal

*High stimulation can worse tremor, dystonia

Electrode position

-bMRI

Tips

-Always save old settings

-Teach patient

>patient programmer

>DBS do's and don'ts
-Fu every mo for 6mo

-Refer to monopolar map, redo if needed

-If no benefit after 2 sessions, do imaging for lead position

Future adjustments

-ET→ Taper off after stimulation

-PD→ Meds for NMS

>STN→ med red 2/2 DKN

>GPi→ can maintain same regimen

-DTN→  retain pre-op meds

Warnings

-Diathermy (‘deep heating’)

-Electrical or radiofrequency therapeutic devices (keep away from head/chest)

-Electrocautery (surgery)

-Lithotripsy

-MRI (heating effect)

-TMS, ECT

-Magnetic fields

-Metal/theft detectors (airport report pacemaker and request pat down)

-Store refrigerators, industrial microwave ovens

-Arc welding equipment, high voltage power lines

-Effect on other medical devices (external defibrillation, cardiac pacemakers)

IPG longevity

PCs→ 3-5y

Impedance

>10,000ohm→ break along contact

 Will not affect stimulation if that contact is unused

-3000-5000→ not problem (but ↑V if CV mode)

-Segments can have ‘high’ bipolar impedance (>10,000 ohm) but not a problem if monopolar impedances wnl

-Low impedance (10-100)→ short in circuit

>Stimulation will be applied to all shorted contacts even if they are not “turned on”

>Quick battery drain if stimulation applied between two shorted contacts (one +, the other -) so do not do

Refine parameters

-If low side effect thresholds, try bipolar or directional:

>Use most optimal contact as negative in bipolar configuration

>Perform monopolar mapping for each segment on the best level

-If unable to achieve benefit with single contact, try double-monopolar stimulation using two adjacent contacts

>Double monopolar if high side effects thresholds (or fractionate current to avoid side effects)

>Double bipolar if low side effects threshold

-Establish best contact first, before changing PW and frequency

>Lower PW if side effects

>Increase frequency for tremor

>Increase PW for more benefit (can also increase amplitude)