Chapter 3 – Electrical Events During One Cardiac Cycle
Goal: From P wave → T wave, understand the full electrical sequence, which vector forms first, and what ECG part represents it.
- Which electrical event happens first in the cardiac cycle
- Which vector is created at each step
- Which ECG component (wave/segment) represents that event
- Complete logic from P → PR → QRS → ST → T
1) What “One Cardiac Cycle” Means (Electrical View)
One cardiac cycle means one complete electrical sequence inside the heart: SA node firing → atrial depolarization → AV delay → ventricular depolarization → ventricular repolarization.
Electrical events happen first → mechanical contraction comes after a short delay.
The ECG displays electrical activity only, not contraction force.
Why does electrical happen before mechanical?
Because contraction requires calcium movement and cross-bridge cycling, which starts after cells depolarize. So ECG is the “trigger,” not the “pump output.”
2) First Electrical Event – Atrial Depolarization (P Wave)
Start point: SA node
The SA node in the upper right atrium initiates the impulse. From there, depolarization spreads across the right atrium and then the left atrium.
- Overall spread is generally downward and leftward
- Atria are thin → vector magnitude is small
- No Purkinje-like rapid network in atria → speed is moderate
P wave = atrial depolarization
P wave is small because the atrial muscle mass is small.
Common confusion: “Does P wave include SA node firing?”
SA node firing starts the process, but the ECG wave you see mainly reflects the spread of depolarization through atrial myocardium, not the tiny SA node itself.
3) Second Electrical Event – AV Nodal Delay (PR Segment)
After atrial depolarization, the impulse reaches the AV node. The AV node conducts slowly, creating a physiological delay.
- AV node tissue is small
- Cells conduct slowly
- Depolarization is largely calcium-dependent (slow upstroke)
- Delay is about ~0.1 sec (conceptually)
- Electrical signal is small and not strongly detected on surface ECG
PR segment = isoelectric line (electrical silence)
It’s not “no electricity in the heart.” It means no large net moving vector is being seen by the lead at that time.
PR segment vs PR interval (must-know difference)
- PR segment = end of P wave to start of QRS (mostly AV nodal delay; flat line)
- PR interval = start of P wave to start of QRS (atrial depolarization + AV conduction time)
4) Third Electrical Event – Onset of Ventricular Depolarization (Septal Depolarization → Q Wave)
From the AV node the impulse travels into the His bundle and then into the bundle branches. The first ventricular region to depolarize is usually the interventricular septum.
Septum tends to depolarize from left → right because the left bundle activates the septum early.
- Small vector (septum is smaller than full ventricular mass)
- Direction described as rightward (and often slightly upward)
- Fast spread due to Purkinje delivery
Q wave = septal depolarization
A small initial negative deflection may appear in leads that view that septal vector as moving away from their positive electrode.
5) Fourth Electrical Event – Major Ventricular Depolarization (R Wave)
After the septum, depolarization spreads through the major bulk of both ventricles: typically inner (endocardium) → outer (epicardium).
- Left ventricle is much thicker → produces a stronger vector
- Right ventricle contributes a smaller vector
Net result: vectors add up into a dominant direction that is commonly described as downward + leftward.
R wave = major ventricular depolarization
This is the biggest wave because ventricular mass is the biggest.
Why is the R wave usually tall?
- Large muscle mass = large magnitude vector
- Rapid Purkinje delivery = quick spread = steep (sharp) deflection
- Many leads are aligned to “see” this net vector well
6) Fifth Electrical Event – Basal Ventricular Depolarization (S Wave)
The final part of ventricular depolarization reaches the basal regions (near the top/base of the heart). Because this is the “last portion,” the net vector direction changes.
- Small vector (last bit of tissue)
- Direction commonly described as upward + rightward
- Fast conduction continues
S wave = late/basal ventricular depolarization
Often appears as a negative deflection after R if that late vector moves away from the lead’s positive electrode.
7) QRS Complex = Complete Ventricular Depolarization
| Wave | Main Electrical Meaning |
|---|---|
| Q | Septal depolarization (early ventricular activation) |
| R | Major ventricular depolarization (bulk of ventricular muscle) |
| S | Late/basal ventricular depolarization (final activation) |
8) ST Segment – Ventricles Fully Depolarized (Flat Line)
After QRS ends, the septum + ventricular walls + base are all depolarized. When all ventricular cells are in a similar electrical state, there is no net moving vector.
- “Electrically silent” on surface ECG (no net vector)
- Cells are largely in the plateau phase
ST segment = isoelectric line
Flat ST does not mean “the heart stopped.” It means “no net vector is moving.”
9) Ventricular Repolarization – T Wave
The last area to depolarize tends to repolarize first
- Depolarization often goes: inside → outside
- Repolarization often goes: outside → inside
Many courses explain this by differences in action potential duration across layers (epicardial vs endocardial) and recovery timing.
T wave = ventricular repolarization
Even though repolarization involves “negative” electrical recovery, the T wave can still be upright in many leads because of vector direction + polarity logic.
Why can the T wave be upright even though it’s repolarization?
Because the ECG deflection depends on vector direction + polarity. Repolarization is not simply “a negative wave.” If the net repolarization vector aligns in a way that produces a positive projection on that lead, the T wave appears upright.
Why Don’t We See Atrial Repolarization?
Atrial repolarization does occur, but it is usually not visible because it happens around the time ventricular depolarization occurs.
- Ventricular depolarization (QRS) has a much larger signal (ventricles are thick).
- The atrial repolarization signal is small and gets “masked” by the QRS complex.
Chapter 3 Summary (Golden Table)
| ECG Component | Electrical Event | What’s happening (simple) |
|---|---|---|
| P wave | Atrial depolarization | Impulse spreads across both atria |
| PR segment | AV nodal delay | Slow conduction; no big net vector on the surface |
| QRS complex | Ventricular depolarization | Septum → bulk ventricles → late/basal regions |
| ST segment | Ventricles fully depolarized | Uniform electrical state; net vector is ~0 |
| T wave | Ventricular repolarization | Recovery phase; vector logic determines T direction |