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Cardiovascular Physiology (心血管生理学)

Cardiovascular Physiology (心血管生理学). Qiang XIA ( 夏强 ), PhD Department of Physiology Zhejiang University School of Medicine Tel: 88206417, 88208252 Email: xiaqiang@zju.edu.cn. System Overview. Components of the cardiovascular system: Heart Vascular system Blood. The heart is the pump

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Cardiovascular Physiology (心血管生理学)

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  1. Cardiovascular Physiology(心血管生理学) Qiang XIA (夏强), PhD Department of Physiology Zhejiang University School of Medicine Tel: 88206417, 88208252 Email: xiaqiang@zju.edu.cn

  2. System Overview • Components of the cardiovascular system: • Heart • Vascular system • Blood

  3. The heart is the pump that propels the blood through the systemic and pulmonary circuits. Red color indicates blood that is fully oxygenated. Blue color represents blood that is only partially oxygenated.

  4. The distribution of blood in a comfortable, resting person is shown here. Dynamic adjustments in blood delivery allow a person to respond to widely varying circumstances, including emergencies.

  5. Functions of the heart • Pumping(泵血) • Endocrine(内分泌) • Atrial natriuretic peptide (ANP) • Brain natriuretic peptide (BNP) • Other bioactivators

  6. The Heart The major external and internal parts of the heart are shown in this diagram. The black arrows indicate the route taken by the blood as it is pumped along.

  7. Valves of the heart

  8. The major types of cardiac muscle: • Atrial muscle • Ventricular muscle • Specialized excitatory and conductive muscle Contractile cells (收缩细胞) Autorhythmic cells (自律细胞)

  9. Conducting system of the heart

  10. Cardiac muscle

  11. Sequence of cardiac excitation The Bundle of His and other parts of the conducting system deliver the excitation to the apex of the heart so that ventricular contraction occurs in an upward sweep. The sinoatrial node is the heart’s pacemaker because it initiates each wave of excitation with atrial contraction.

  12. General process of excitation and contraction of cardiac muscle • Initiation of action potentials in sinoatrial node • Conduction of action potentials along specialized conductive system • Excitation-contraction coupling • Muscle contraction

  13. Transmembrane potentials recorded in different heart regions

  14. Transmembrane potential of ventricular cells and its ionic mechanisms Resting Potential: -90 mV Action Potential • Phase 0: Depolarization • Phase 1: Early phase of rapid repolarization • Phase 2: Plateau(平台期) • Phase 3: Late phase of rapid repolarization • Phase 4: Resting phase

  15. Ionic mechanisms • Resting potential • K+ equilibrium potential • Na+-inward background current • Electrogenic Na+-K+ pump

  16. The action potential of a myocardial pumping cell. • Phase 0 • Threshold potential (-70mV) • Opening of fast Na+ channel • Regenerative cycle(再生性循环)

  17. Phase 1 • Transient outward current, Ito K+ current • activated at –20 mV • opening for 5~10 ms

  18. Phase 2 Inward current Outward current (Ca2+ & Na+) (K+ current)

  19. Types of Ca2+ channels in cardiac cells: • (1) L-type (long-lasting) (Nowycky, 1985) • (2) T-type (transient) (Nowycky, 1985)

  20. Ca2+ channels • L-type T-type Duration of current long-lasting transient Activation kinetics slower faster Inactivation kinetics slower faster Threshold high (-35mV) Low (-60mV) cAMP/cGMP-regulated Yes No Phosphorylation-regulated Yes No Openers Bay-K-8644 - Blockers varapamil Tetramethrin nifedipine, diltiazem Ni2+ Inactivation by [Ca2+]i Yes slight Patch-clamp recording run-down relatively stable

  21. Outward current (K+ current): • (1) inward rectifier K+ current (IK1) • (2) delayed rectifier K+ current (IK)

  22. Phase 3 Inactivation of Ca2+ channel Outward K+ current dominates IK: Progressively increased IK1: Regenerative K+ Outward Current

  23. Phase 4 Na+-Ca2+ exchange Sarcolemmal Ca2+ pump SR Ca2+ pump Na+-K+ pump

  24. Transmembrane potentials recorded in different heart regions

  25. Transmembrane potential of autorhythmic cells and its ionic mechanisms

  26. Purkinje cells: Fast response autorhythmic cells 4

  27. Contractile cellsAutorhythmic cells Phase 4 stable potentialPhase 4 spontaneous depolarization (4期自动去极化) Resting potential Maximal repolarization potential (最大复极电位)

  28. Ionic mechanism • Phase 0~3:similar to ventricular cells • Phase 4: • (1) If – Funny current, Pacemaker current(起搏电流) • (2) Ik Decay(钾电流衰减)

  29. Characteristics of If channel • Na+, K+ • Voltage- & time-dependent Activation── Repolarized to -60mV Full activation── Hyperpolarized to -100mV Inactivation── Depolarized to -50mV • Blocked by Cesium (Cs), not by TTX

  30. Sinoatrial cells

  31. 0 3 4 Sinoatrial cells: Slow response autorhythmic cells • Maximal repolarization potential -70mV • Threshold potential -40mV • Phase 0, 3, 4

  32. 0 3 4 Ionic mechanism • Phase 0: ICa (ICa,L)

  33. 0 3 4 • Phase 3: • Inactivation of L-type Ca2+ channel • Outward K+ current (Ik)

  34. Phase 4: • Ik decay Inactivated when repolarized to -60mV • ICa,T Activated when depolarized to -50mV • If

  35. The action potential of anautorhythmic cardiac cell.

  36. During which phase of the ventricular action potential is the membrane potential closest to the K+ equilibrium potential? (A) Phase 0 (B) Phase 1 (C) Phase 2 (D) Phase 3 (E) Phase 4

  37. During which phase of the ventricular action potential is the conductance to Ca2+ highest? (A) Phase 0 (B) Phase 1 (C) Phase 2 (D) Phase 3 (E) Phase 4

  38. Which phase of the ventricular action potential coincides with diastole? (A) Phase 0 (B) Phase 1 (C) Phase 2 (D) Phase 3 (E) Phase 4

  39. Electrocardiogram (ECG)(心电图) The electrocardiogram (ECG) measures changes in skin electrical voltage/potential caused by electrical currents generated by the heart

  40. The relationship between the electrocardiogram (ECG), recorded as the difference between currents at the left and right wrists, and an action potential typical of ventricular myocardial cells. Electrocardiogram (ECG)

  41. I aVR aVL V1 V2 V3 V4 V5 V6 III II aVF The standard 12 lead ECG Einthoven’s Triangle Limb leads (Bipolar) (I, II, III) Augmented limb leads (Unipolar) (aVR, aVL, aVF) Chest leads (Unipolar) (V1, V2, V3, V4, V5, V6) Willem Einthoven: Dutch physiologist. He won a 1924 Nobel Prize for his contributions to electrocardiography.

  42. Placement of electrodes in electrocardiography

  43. 0.04 sec • ECG interpretation • Measurements • Rhythm analysis • Conduction analysis • Waveform description • Comparison with previous ECG (if any) Normal ECG

  44. P wave: the sequential depolarization of the right and left atria • QRS complex: right and left ventricular depolarization • ST-T wave: ventricular repolarization • U wave: origin for this wave is not clear - but probably represents "afterdepolarizations" in the ventricles

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