Control of temperaturePeripheral va

Control of temperature
Peripheral vasoconstriction occurs in hypovolaemic
shock as the body compensates to protect the vital
organs; the body temperature is likely to decrease
as a result of this mechanism and it is vital the VN
monitors and acts accordingly (Wemple, 2010). The
patient’s rectal temperature on admission was 36.80C;
by using a patient care plan and applying the knowledge
that hypothermia was likely to occur, preventative
measures were put into place. Dix et al (2006) define
hypothermia as a sub-normal body temperature
relating to core temperatures between 32–370C. They
describe the general depressant effect that occurs
with potential detrimental consequences, especially
in an already compromised patient that has impaired
heat production and conservation mechanisms. The
metabolic rate decreases by approximately 10% for
each 10C drop in core temperature (Hobbs, 2002). The
cardiovascular system is affected as bradycardia and
a reduction in cardiac output subsequently cause a
decline in arterial blood pressure. The risk of cardiac
arrhythmias is greater as the electrical conduction of
the heart is affected. Blood clotting times rise due to
decreased activity of clotting factors and blood viscosity
may also increase, which heightens the risk of
clotting. Shivering increases oxygen requirements,
decreases effective ventilation and increases pain levels
(Clark, 2003; Dix et al, 2006; Archer, 2007; Lamb,
2009). Wemple (2010) and Gurney (2008) describe
bradycardia as a common result of hypovolaemic
shock in felines and so this was already a concern l
in this case.