Ch4 Cardiovascular System
Blood vessels
- Arteries: carry blood away from the heart
- Veins: carry blood to the heart
Pulmonary circulation
- Right ventricle → left atrium
Systemic circulation
- Left ventricle → aorta → right atrium via vena cava
Key note:
- The right heart is less oxygenated.
Blood movement
Blood is moved via bulk flow.
Cardiac cycle (process of blood)
- blood enters atria from veins
- AV valves open
- blood enters ventricle (about 80% full)
- atria contract (remaining 20%)
- atria relax, ventricle contracts, AV valve closes (lub)
- pulmonary / aortic valve opens
- pulmonary / aortic valve closes (dub)
Electrical signaling
Cell types
-
Contractile cells
-
contract when they receive a signal
-
Conducting cells
-
do not contract
- controlled by the Cardiac Conduction System (CCS)
Key note:
- The CCS can generate signals and drive pumping on its own.
Cardiac Conduction System (CCS) pathway
- Sinoatrial (SA) node (right atrium)
- internodal pathway
-
Atrioventricular (AV) node (right atrium)
-
delay for 100 ms
- bundle of His
- left and right ventricles via Purkinje fibers
ECG mapping
- P wave: voltage increase in atrial muscle cells
- QRS complex: ventricular contraction
- T wave: ventricular relaxation
Pacemaker mechanisms (autorhythmicity)
HCN4 (“funny channel”)
Hyperpolarization-activated cyclic nucleotide-gated channel 4 (HCN4):
- opens when voltage decreases
- contributes to autorhythmicity
- opens when \(V < -40,\text{mV}\) and with cAMP
Pacemaker potential
- pacemaker potential is the slow influx of Na\(^+\)
- cardiac muscle cells do not have leaking Na\(^+\) channels
Interpreting the waveform
- the upward is sodium, which is the start of P wave (atria) or QRS (ventricle)
- the first downward is K\(^+\), which is the end of P wave (atria) or QRS (ventricle)
- the plateau is the gap between P and QRS or QRS and T
- the last downward is K\(^+\), which is QRS (atria) or T (ventricle)
Vessel structure
Layers of a large artery
- lumen
- endothelium
- multiple elastic layers
- many layers of connective tissue and muscle
Arteriole
- lumen
- endothelium
- many layers of muscle
Capillary
- lumen
- endothelium, with intracellular clefts (proteins unable to flow through)
Venule
- lumen
- endothelium
Large vein
- lumen (wide)
- endothelium
- few elastic layers
- few smooth muscle and connective tissue layers
- with valves
Mean Arterial Pressure (MAP)
[ \text{MAP} = \text{CO} \times \text{TPR} ] where:
- CO = cardiac output
- TPR = total peripheral resistance
MAP feedback loop
- Controller: medulla oblongata
- Sensor: mechanoreceptor neurons
-
Actuating signals:
-
parasympathetic firing rate
- sympathetic firing rate
Effectors
-
SA node
-
\(\beta\)-adrenergic for SNS
- nAChRs for PNS
-
arteriolar smooth muscle
-
\(\alpha\)-adrenergic
Autonomic pathways
Sympathetic nervous system (SNS)
NT: noradrenaline
| SA node | Arteriole smooth muscle | |
|---|---|---|
| Receptor | \(\beta\)-adrenergic receptor (GPCR) | \(\alpha\)-adrenergic receptor (GPCR) |
| Leads to | increase cAMP on F channel; increase heart rate and CO | increase smooth muscle contraction; increase TPR |
Parasympathetic nervous system (PNS)
NT: ACh
| Heart | |
|---|---|
| Receptor | muscarinic ACh receptor (mAChR) |
| Leads to | drop cAMP; increase K\(^+\) conductance; decrease heart rate and CO |
Local change (active hyperemia)
- high level of cellular activity leads to more blood flow to that area (active hyperemia)
- increased arteriole diameter increases blood flow