Shock pathophysiology: Difference between revisions

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'''BP = CO x PR'''
'''BP = CO x PR'''


Therefore a loss of [[blood pressure]] can be due to a fall in [[cardiac output]] as will be seen in cardiac disease, outflow obstruction or haemorrhagic shock. [[Blood pressure]] may also fall as peripheral resistance falls due to massive [[vasodilatation]] as may be seen in [[sepsis]].
Therefore a loss of [[blood pressure]] can be due to a fall in [[cardiac output]] as will be seen in cardiac disease, outflow obstruction or [[hemorrhagic shock]]. [[Blood pressure]] may also fall as peripheral resistance falls due to massive [[vasodilatation]] as may be seen in [[sepsis]].


===Preload and Afterload===
===Preload and Afterload===


;[[Preload]] : This is a concept rather than a true value. It cannot be measured as such, but various measureable physiological parameters can act as surrogates, e.g. CVP or pulmonary artery wedge pressure. It can be thought of as the filling pressure of heart chambers. So long as the heart is not overwhelmed, the greater the initial filling of a heart chamber, the greater the force of contraction.
;[[Preload]]: This is a concept rather than a true value. It cannot be measured as such, but various measurable physiological parameters can act as surrogates, e.g. CVP or pulmonary artery wedge pressure. It can be thought of as the filling pressure of heart chambers. So long as the heart is not overwhelmed, the greater the initial filling of a heart chamber, the greater the force of contraction.


;[[Afterload]] : This can be thought of as the amount of force required for the heart to eject blood. It is influenced by [[preload]], systemic vascular resistance and external pressure (e.g. in postive pressure ventilation).
;[[Afterload]]: This can be thought of as the amount of force required for the heart to eject blood. It is influenced by [[preload]], systemic vascular resistance and external pressure (e.g. in positive pressure ventilation).


===Homeostatic Mechanisms===
===Homeostatic Mechanisms===

Revision as of 17:21, 5 March 2013

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]

Pathophysiology

In general, blood pressure (BP) can be factored as a product of cardiac output (CO) x peripheral resistance (PR, also known as systemic vascular resistance). Cardiac output itself is determined by stroke volume (SV) x heart rate (HR):

CO = HR x SV

BP = CO x PR

Therefore a loss of blood pressure can be due to a fall in cardiac output as will be seen in cardiac disease, outflow obstruction or hemorrhagic shock. Blood pressure may also fall as peripheral resistance falls due to massive vasodilatation as may be seen in sepsis.

Preload and Afterload

Preload
This is a concept rather than a true value. It cannot be measured as such, but various measurable physiological parameters can act as surrogates, e.g. CVP or pulmonary artery wedge pressure. It can be thought of as the filling pressure of heart chambers. So long as the heart is not overwhelmed, the greater the initial filling of a heart chamber, the greater the force of contraction.
Afterload
This can be thought of as the amount of force required for the heart to eject blood. It is influenced by preload, systemic vascular resistance and external pressure (e.g. in positive pressure ventilation).

Homeostatic Mechanisms

A fall in blood pressure usually results in

References