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Primary Function of the Cardiovascular System
Cardiovascular Physiology
What is the medium for transport?
Modes of Transport: Bulk Flow
What happens if the heart stops?
Ischemia
Transient Ischemia
Persistent Ischemia
Primary Cardiovascular Dysfunctions
Congenital Primary Cardiovascular Dysfunction
Acquired Primary Cardiovascular Dysfunction
Secondary cardiovascular dysfunctions
Shock
Types of Shock: Hemorrhagic
Types of Shock: Cardiogenic
Types of Shock: Septic
Types of Shock: Endotoxic
Substances transported by the Cardiovascular System (4)
Perfusion Pressure
Modes of Transport: Diffusion
Functional Arrangement of the Cardiovascular System: Heart
Cardiac Output
Hematocrit (PCV)
If you have high plasma concentration and low cell concentration in the blood, this could indicate:
If you have low plasma concentration and high cell concentration, this could indicate:
Blood
Gas Transport
What is the buffy coat in blood?
Cell Types of The Heart
Cardiomyocytes:
Contractile Cells
Cardiomyocytes:
Pacemaker Cells
Autorhythmic
Non-cardiomyocyte Cells:
Fibroblasts
Endothelial and Smooth Muscle Cells
Neural Cells
When we die, our heart keeps beating for a while. What causes the actual cessation of our autorhythmic heart?
Secondary Cardiovascular Dysfunctions:
Pulmonary Edema
Secondary Cardiovascular Dysfunction:
Anesthetic Overdose
Secondary Cardiovascular Dysfunctions:
Burns or Persistent vomiting or diarrhea
SA node:
AV node
AV bundle (Bundle of his)
Purkinje fibres
Left/Right bundle branches
Sympathetic Effects on the Heart
Chronotropy
Parasympathetic Effects on the Heart
Action potentials in pacemaker cells
Pacemaker Potential
Pacemaking in the Heart
Conduction System of the Heart
What does the extremely rapid conduction of an action potential allow for?
Electrocardiogram (ECG)
Einthoven Triangle
Arrhythmias: Classification (2)
Arrhythmias: Disorders of Rate
Arrhythmias: Disorders of rhythm
What does decreased cardiac output lead to?
Arrhythmia Definition
Arrhythmias: Causes
Arrhythmias: Problems with the formation of APs
Arrhythmias: Problems with the formation of APs - Treatment
Arrhythmias: Problems with Propagation of APs AV node block- Definition and Classifications
Arrhythmias: Problems with propagation of AP's: Atrial Conduction Abnormalities
Cardiac Cycle
Systole
Diastole
Stroke volume (SV)
Cardiac Physiology
Systole
Diastole
Cardiac Cycle
Factors Affecting cardiac output causing an increase in cardiac output
Contractility
Normal heart sounds (lub dub)
Cardiac Murmurs
Systolic Murmurs
Diastolic Murmurs
Patent ductus arteriosis
Cardiac Defects that cause murmurs usually lead to:
Pathological Consequences of Cardiac Defects - Mitral Regurgitation:
Pathological Consequences of Cardiac Defects - Patent Ductus
Pathological Consequences of Cardiac Defects - Mitral Stenosis
Systemic circulation
Compliance
Vascular Resistance
Arterioles
Blood flow to each organ is determined by
Pulmonary Circulation
Mean Arterial Pressure
Blood/Pulse Pressure Calculation
Capillaries
Oncotic Forces
Hydrostatic forces
Onocotic and Hydrostatic forces under normal conditions
Edema
Safety Mechanisms that limit the degree of edema
What can lead to edema?
Local Control of Blood Flow
Control of Vascular Resistance: Intrinsic Factors
Control of Vascular Resistance: Extrinsic Factors
2 intrinsic factors in the control of vascular resistance
Metabolic Control
Metabolic Control of Blood Flow: Active Hyperemia
Reactive Hyperemia
Mechanical Compression (MC)
Autoregulation
Paracrine Signals
Paracrine signals: Endothelin - 1
Paracrine signals: Nitric Oxide (NO) (gas)
Histamine
Bradykinin
Neurohumoral Control of the Cardiovascular System
ANS controls of the CV system
Baroreceptors
Baroreceptor Reflex
Atrial Volume Receptors
Renal Perfusion
Heart (pump) Failure
Bilateral Heart failure
Left- or Right-sided heart failure
When heart can't maintain pumping capability, 3 things occur:
Left-sided heart failure
Right-sided heart failure
Compensations of Heart failure
Complications Secondary to Heart failure
Decompensation in LV failure
Consequences and Compensations of Hemorrhage initiated by:
Behavioural and Hormonal Responses to Hemorrhage
Muscle Pump
Amphibian Cardiovascular System
Reptilian Cardiovascular System
Respiratory functions
Basal metabolism
Basal Metabolic Rate (BMR)
Gas Exchange
Processes involved in gas exchange
Ventilation
VE
VT
f
VA
VD
Conducting airways
Types of Dead-Space
Physiological deadspace
Dead space/tidal volume ratio (VD/VT)
Inhalation
Exhalation
In running animals, ventilation is synchronized with gait. During inhalation and exhalation:
Pulmonary Surfactant
Lung compliance
Pleural fluid
Atelectasis
Frictional Resistance of the Airways
Control of airway diameter
Dynamic Compression
Collateral ventilation
Air distribution in the lung
Intrathoracic airways
2 circulatory Systems for blood flow to the lung
Bronchial Circulation
Pulmonary Circulation
Pulmonary Capillaries
Pulmonary Veins
Alveolar capillaries
Distribution of Pulmonary Blood Flow influenced by 2 main factors
Pulmonary Vascular Resistance (PVR)
In systemic circulation what provides the majority of resistance blood flow?
Transmural Pressure
Vascular Smooth Muscle
Alveolar Hypoxia and Vascular Resistance
Hypoxic Vasoconstriction
Exercise and Pulmonary Circulation
Partial Pressure/Fractional Composition
Alveolar Gas Composition
Alveolar Hypoventilation
Alveolar Hyperventilation
Causes of alveolar hypoventilation
Rate of Gas movement (Voxygen) b/w alveolus and blood determined by 4 things:
1) Physical property of gas (D)
2) Alveolar surface area avail for diffusion (A)
3) Thickness of air-blood barrier (x)
4) Driving pressure gradient
Gas exchange b/w blood and tissue
Gas Exchange b/w blood and tissue during exercise
V/Q ratio
Oxygen Transport
Hemoglobin (Hb)
Hemoglobin Affinity for Oxygen (1)
Hemoglobin Affinity for Oxygen (2)
Hemoglobin Affinity for Oxygen (3)
Hemoglobin Affinity for Oxygen (4)
Hb colour
Carbon monoxide affinity for Hb
Carbon Dioxide transport
Gas transport during exercise
During exercise, what is increased oxygen extraction due to?
Regulation of ventilation
Central Control of Respiration
Types of Pulmonary Airway Receptors: Slow adapting stretch receptors
Types of Pulmonary Airway Receptors: Irritant Receptors (rapidly adapting stretch receptors)
Types of Pulmonary and Airway Receptors: C Fibres