THE CARDIOVASCULAR SYSTEM. Heart 2

Transcription

1 THE CARDIOVASCULAR SYSTEM Heart 2

2 PROPERTIES OF CARDIAC MUSCLE Cardiac muscle Striated Short Wide Branched Interconnected Skeletal muscle Striated Long Narrow Cylindrical

3 PROPERTIES OF CARDIAC MUSCLE Intercalated discs passage of ions Numerous large mitochondria 25 35% of cell volume Able to utilize many food molecules Example: lactic acid

4 Nucleus Intercalated discs Cardiac muscle cell Gap junctions Desmosomes (a) Figure 18.11a

5 Cardiac muscle cell Intercalated disc Mitochondrion Nucleus T tubule Mitochondrion Sarcoplasmic reticulum Z disc Nucleus (b) Sarcolemma I band A band I band Figure 18.11b

6 PROPERTIES OF CARDIAC MUSCLE Some cells are myogenic Heart contracts as a unit or not at all Sodium channels leak slowly in specialized cells Spontaneous deoplarization Compare to skeletal muscle

7 Action Potential in Myogenic Cells of the Heart Action potential Threshold Pacemaker potential 1 Pacemaker potential 2 Depolarization The 3 Repolarization is due to This slow depolarization is due to both opening of Na + channels and closing of K + channels. Notice that the membrane potential is never a flat line. action potential begins when the pacemaker potential reaches threshold. Depolarization is due to Ca 2+ influx through Ca 2+ channels. Ca 2+ channels inactivating and K + channels opening. This allows K + efflux, which brings the membrane potential back to its most negative voltage. Figure 18.13

8 Membrane potential (mv) Tension (g) Action Potential of Contractile Cardiac Muscle Cells 1 2 Absolute refractory period Time (ms) 3 Action potential Plateau Tension development (contraction) 1 Depolarization is due to Na + influx through fast voltage-gated Na + channels. A positive feedback cycle rapidly opens many Na + channels, reversing the membrane potential. Channel inactivation ends this phase. 2 Plateau phase is due to Ca 2+ influx through slow Ca 2+ channels. This keeps the cell depolarized because few K + channels are open. 3 Repolarization is due to Ca 2+ channels inactivating and K + channels opening. This allows K + efflux, which brings the membrane potential back to its resting voltage. Figure 18.12

9 CONDUCTION SYSTEM OF THE HEART Terms Systole versus diastole Specialized cardiac cells Initiate impulse Conduct impulse

10 CONDUCTION SYSTEM OF THE HEART Conduction pathway SA node (pacemaker) atrial depolarization and contraction AV node bundle of His right and left bundle branches purkinje fibers myocardium contraction of ventricles

11 Conduction Pathway 1 The sinoatrial (SA) node (pacemaker) generates impulses. Internodal pathway 2 The impulses pause (0.1 s) at the atrioventricular (AV) node. 3 The atrioventricular (AV) bundle connects the atria to the ventricles. 4 The bundle branches conduct the impulses through the interventricular septum. 5 The Purkinje fibers depolarize the contractile cells of both ventricles. Superior vena cava Right atrium Left atrium Purkinje fibers Interventricular septum (a) Anatomy of the intrinsic conduction system showing the sequence of electrical excitation (Intrinsic Innervation) Figure 18.14a

12 CONDUCTION SYSTEM OF THE HEART 1. Sinoatrial (SA) node (pacemaker) Generates impulses about times/minute (sinus rhythm) Depolarizes faster than any other part of the myocardium 2. Atrioventricular (AV) node Delays impulses approximately 0.1 second Depolarizes 50 times per minute in absence of SA node input

13 CONDUCTION SYSTEM OF THE HEART 3. Atrioventricular (AV) bundle (bundle of His) Only electrical connection between the atria and ventricles 4. Right and left bundle branches Two pathways in the interventricular septum that carry the impulses toward the apex of the heart 5. Purkinje fibers Complete the pathway into the apex and ventricular walls

14 CONDUCTION SYSTEM OF THE HEART Intrinsic innervation External influences Normal: Average = 70 bpm Range = bpm

15 The vagus nerve (parasympathetic) decreases heart rate. Cardioacceleratory center Dorsal motor nucleus of vagus Cardioinhibitory center Medulla oblongata Sympathetic trunk ganglion Thoracic spinal cord Sympathetic trunk Sympathetic cardiac nerves increase heart rate and force of contraction. SA node AV node Parasympathetic fibers Sympathetic fibers Interneurons Figure 18.15

16 HOMEOSTATIC IMBALANCES Defects in the intrinsic conduction system may result in 1. Arrhythmias: irregular heart rhythms 2. Bradycardia < 60 bpm 3. Tachycardia >100 bpm 4. Maximum is about 300 bpm

17 ELECTROCARDIOGRAPHY A composite of all the action potentials generated by nodal and contractile cells at a given time Represents movement of ions = bioelectricity Three waves 1. P wave: electrical depolarization of atria 2. QRS complex: ventricular depolarization 3. T wave: ventricular repolarization

18 Sinoatrial node QRS complex Atrial depolarization Ventricular depolarization Ventricular repolarization Atrioventricular node P-Q Interval S-T Segment Q-T Interval Figure 18.16

19 SA node R Depolarization Repolarization P T R AV node Q S 1 Atrial depolarization, initiated by the SA node, causes the P wave. R P T Q S 4 Ventricular depolarization is complete. R P T P T Q S 2 With atrial depolarization complete, the impulse is delayed at the AV node. R Q S 5 Ventricular repolarization begins at apex, causing the T wave. R P T P T Q S 3 Ventricular depolarization begins at apex, causing the QRS complex. Atrial repolarization occurs. Q S 6 Ventricular repolarization is complete. Figure 18.17

20 (a) Normal sinus rhythm. (b) Junctional rhythm. The SA node is nonfunctional, P waves are absent, and heart is paced by the AV node at beats/min. (c) Second-degree heart block. Some P waves are not conducted through the AV node; hence more P than QRS waves are seen. In this tracing, the ratio of P waves to QRS waves is mostly 2:1. (d) Ventricular fibrillation. These chaotic, grossly irregular ECG deflections are seen in acute heart attack and electrical shock. Figure 18.18

21 THE CARDIAC CYCLE All events associated with blood flow through the heart during one complete heartbeat Systole contraction (ejection of blood) Diastole relaxation (receiving of blood)

22 THE CARDIAC CYCLE Three events 1) Recordable bioelectrical disturbances (EKG) 2) Contraction of cardiac muscle 3) Generation of pressure and volume changes Blood flows from areas of higher pressure to areas of lower pressure Valves prevent backflow

23 THE CARDIAC CYCLE Ventricular filling ventricular systole Backpressure closes AV valves = isovolumetric contraction Ventricular pressure > aortic pressure semilunar valves open Portion of ventricular contents ejected

24 Ventricular volume (ml) Pressure (mm Hg) EKG Electrocardiogram Heart sounds P QRS 1st Left heart T 2nd P Dicrotic notch Pressure changes Atrial systole Left atrium Left ventricle Aorta Changes in volume EDV SV ESV Atrioventricular valves Aortic and pulmonary valves Phase Open Closed Closed Open 1 2a 2b 3 Open Closed 1 Contraction Left atrium Right atrium Left ventricle Right ventricle Ventricular filling Atrial Isovolumetric Ventricular Isovolumetric contraction contraction phase ejection phase relaxation 1 2a 2b 3 Ventricular filling Ventricular filling (mid-to-late diastole) Ventricular systole (atria in diastole) Early diastole Figure 18.20

25 HEART SOUNDS Two sounds associated with closing of heart valves First sound occurs as AV valves close and signifies beginning of systole = Lub Second sound occurs when SL valves close at the beginning of ventricular diastole = Dub Heart murmurs = abnormal heart sounds Most often indicative of valve problems

26 Aortic valve sounds heard in 2nd intercostal space at right sternal margin Pulmonary valve sounds heard in 2nd intercostal space at left sternal margin Mitral valve sounds heard over heart apex (in 5th intercostal space) in line with middle of clavicle Tricuspid valve sounds typically heard in right sternal margin of 5th intercostal space Figure 18.19

27 Ventricular volume (ml) Pressure (mm Hg) Heart sounds Electrocardiogram P QRS 1st Left heart T 2nd P Dicrotic notch Pressure changes Atrial systole Left atrium Left ventricle Aorta Changes in volume EDV SV ESV Atrioventricular valves Aortic and pulmonary valves Phase Open Closed Closed Open 1 2a 2b 3 Open Closed 1 Left atrium Right atrium Left ventricle Right ventricle Ventricular filling Atrial Isovolumetric Ventricular Isovolumetric contraction contraction phase ejection phase relaxation 1 2a 2b 3 Ventricular filling Ventricular filling (mid-to-late diastole) Ventricular systole (atria in diastole) Early diastole Figure 18.20

28 Mitral Stenosis HEART SOUNDS

29 HEART SOUNDS Valvular insufficiency (regurgitation)

30 CARDIAC OUTPUT (CO) Definition: volume of blood pumped by each ventricle in one minute Minute volume 2 major factors Stroke volume Heart rate

31 CARDIAC OUTPUT CO (ml/min) = heart rate (HR) x stroke volume (SV) HR = number of beats per minute SV = volume of blood pumped out by a ventricle with each beat (ml/min)

32 CARDIAC OUTPUT Stroke volume Difference between EDV and ESV EDV-ESV=SV Average is about 75 ml

33 Ventricular volume (ml) Pressure (mm Hg) EKG Electrocardiogram Heart sounds P QRS 1st Left heart T 2nd P Dicrotic notch Pressure changes Atrial systole Left atrium Left ventricle Aorta Changes in volume EDV SV ESV Atrioventricular valves Aortic and pulmonary valves Phase Open Closed Closed Open 1 2a 2b 3 Open Closed 1 Left atrium Right atrium Left ventricle Right ventricle Ventricular filling Atrial Isovolumetric Ventricular Isovolumetric contraction contraction phase ejection phase relaxation 1 2a 2b 3 Ventricular filling Ventricular filling (mid-to-late diastole) Ventricular systole (atria in diastole) Early diastole Figure 18.20

34 CARDIAC OUTPUT (CO) At rest CO (ml/min) = HR (75 beats/min) SV (70 ml/beat) = 5.25 L/min Maximal CO is 4 5 times resting CO in nonathletic people CO may reach 30 L/min in trained athletes Cardiac reserve Difference between resting and maximal CO

35 THOUGHT QUESTION If you increase stroke volume what would happen to cardiac output? Remember: CO = HR x SV

36 REGULATION OF STROKE VOLUME Stroke Volume Three main factors affect SV Preload Contractility Afterload

37 REGULATION OF STROKE VOLUME Preload Frank-Starling law of the heart Degree of stretch of cardiac muscle cells before they contract Cardiac muscle exhibits a length-tension relationship At rest, cardiac muscle cells are shorter than optimal length Slow heartbeat and exercise increase venous return Increased venous return distends (stretches) the ventricles and increases contraction force

38 REGULATION OF STROKE VOLUME Contractility Contractile strength at a given muscle length, independent of muscle stretch and EDV Agents increasing contractility Increased Ca 2+ influx Sympathetic stimulation Hormones Thyroxin, glucagon, and epinephrine Agents decreasing contractility Calcium channel blockers Increase SV Decrease ESV

39 REGULATION OF STROKE VOLUME Afterload Pressure that must be overcome for ventricles to eject blood Hypertension increases afterload Results in increased ESV and reduced SV

40 CONTROL OF HEART RATE Sympathetic nervous system Norepinephrine Increased SA node firing rate Faster conduction through AV node Increases excitability of heart Parasympathetic nervous system Vagus nerve Decreases HR Who dominates at rest?

41 Exercise (by skeletal muscle and respiratory pumps; see Chapter 19) Heart rate (allows more time for ventricular filling) Bloodborne epinephrine, thyroxine, excess Ca 2+ Exercise, fright, anxiety Venous return Contractility Sympathetic activity Parasympathetic activity EDV (preload) ESV Stroke volume Heart rate Cardiac output Initial stimulus Physiological response Result Figure 18.22

42 The vagus nerve (parasympathetic) decreases heart rate. Cardioacceleratory center Dorsal motor nucleus of vagus Cardioinhibitory center Medulla oblongata Sympathetic trunk ganglion Thoracic spinal cord Sympathetic trunk Sympathetic cardiac nerves increase heart rate and force of contraction. SA node AV node Parasympathetic fibers Sympathetic fibers Interneurons Figure 18.15

43 Other factors CONTROL OF HEART RATE

44 QUESTIONS?