The
cranium encloses a fixed-volume space that holds three components:
blood,
cerebrospinal fluid (CSF), and very soft tissue (the
brain). While both the blood and CSF have poor compression capacity, the brain is easily compressible. Every increase of ICP can cause a change in tissue perfusion and an increase in stroke events.
From resistance CPP can be defined as the pressure gradient causing
cerebral blood flow (CBF) such that : CBF = CPP/CVR where: :CVR is cerebrovascular resistance
By intracranial pressure An alternative definition of CPP is: : CPP=MAP-ICP where: :MAP is
mean arterial pressure :ICP is
intracranial pressure :JVP is
jugular venous pressure This definition may be more appropriate if considering the circulatory system in the brain as a
Starling resistor, where an external pressure (in this case, the intracranial pressure) causes decreased blood flow through the vessels. In this sense, more specifically, the cerebral perfusion pressure can be defined as either: : CPP = MAP - ICP (if ICP is higher than JVP) or : CPP = MAP - JVP (if JVP is higher than ICP). Physiologically, increased
intracranial pressure (ICP) causes decreased blood perfusion of
brain cells by mainly two mechanisms: • Increased ICP constitutes an increased
interstitial hydrostatic pressure that, in turn, causes a decreased
driving force for capillary filtration from intracerebral blood vessels. • Increased ICP compresses cerebral arteries, causing increased cerebrovascular resistance (CVR). FLOW Ranging from ^{20\,\textrm{mL}}/_{100\,\textrm{g}{\cdot}\textrm{min}} in white matter to ^{70\,\textrm{mL}}/_{100\,\textrm{g}{\cdot}\textrm{min}} in grey matter. ==Autoregulation==