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The student understands the basic principles of cardiovascular transport and its role in maintaining homeostasis:

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  • Defines convective transport and diffusion and lists the factors that determine the rate of each.
  • Given data, uses the Fick principle to calculate the rate of removal of a solute from blood as it passes through an organ.
  • Describes how capillary wall permeability to a solute is related to the size and lipid solubility of the solute.
  • Lists the factors that influence transcapillary fluid movement and, given data, predicts the direction of transcapillary fluid movement.
  • Describes the lymphatic vessel system and its role in preventing fluid accumulation in the interstitial space.

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The student understands the physical factors that regulate blood flow through and blood volume in the various components of the vasculature:

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  • Given data, calculates the vascular resistances of networks of vessels arranged in parallel and in series.
  • Describes differences in the blood flow velocity in the various segments and how these differences are related to their total cross-sectional area.
  • Describes laminar and turbulent flow patterns and the origin of flow sounds in the cardiovascular system.
  • Identifies the approximate percentage of the total blood volume that is contained in the various vascular segments in the systemic circulation.
  • Defines peripheral venous pool and central venous pool.
  • Describes the pressure changes that occur as blood flows through a vascular bed and relates them to the vascular resistance of the various vascular segments.
  • States how the resistance of each consecutive vascular segment contributes to an organ's overall vascular resistance and, given data, calculates the overall resistance.
  • Defines total peripheral resistance (systemic vascular resistance) and states the relationship between it and the vascular resistance of each systemic organ.
  • Defines vascular compliance and states how the volume–pressure curves for arteries and veins differ.
  • Predicts what will happen to venous volume when venous smooth muscle contracts or when venous transmural pressure increases.
  • Describes the role of arterial compliance in storing energy for blood circulation.
  • Describes the auscultation technique for determining arterial systolic and diastolic pressures.
  • Identifies the physical bases of the Korotkoff sounds.
  • Indicates the relationship between arterial pressure, cardiac output, and total peripheral resistance and predicts how arterial pressure will be altered when cardiac output and/or total peripheral resistance changes.
  • Given arterial systolic and diastolic pressures, estimates mean arterial pressure.
  • Indicates the relationship between pulse pressure, stroke volume, and arterial compliance and predicts how pulse pressure will be changed by changes in stroke volume, or arterial compliance.
  • Describes how arterial compliance changes with age and how this affects arterial pulse pressure.

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Recall from Chapter 1 that the primary job of the cardiovascular system is to maintain “homeostasis” within a body that contains billions of closely spaced individual cells. Homeostasis implies that each and every cell in the body is continually bathed in a local environment of constant composition that is optimal for cell function. In essence, the peripheral vascular system is a sophisticated ...

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