homeostasis and physiological range

homeostasis and physiological ranges for this species.
Disturbances in venous blood acid–base status (pCO2
and pH) are frequently observed in older birds, which
may be due to relative differences in their body sizes or
may reflect the consequences of an increased metabolic
demand in the bigger birds (Korte et al., 1999). Sometimes,
acute respiratory acidosis may results from hypoventilation,
which may be due to loss of respiratory
drive, body mass, chest wall capacity, or rapid shallow
breathing, but this can be quickly corrected through intracellular
buffering of hydrogen and renal retention of
HCO3
− (compensatory mechanism of metabolic alkalosis)
with a slight numerical increase in HCO3
−. This
is based on the fact that 3 systems (blood buffer, respiratory,
and renal systems) function interdependently
to regulate and maintain acid–base balance. The respiratory
system (lungs) regulates levels of CO2 in the
blood by increasing or decreasing ventilation, while the
urinary system (kidneys) modulates levels of HCO3
−
in the blood by selectively generating, retaining, or
excreting HCO3
− ions. The kidneys also regulate H+
ion excretion in response to blood CO2 levels (higher
blood CO2 or lower pH) leads to faster H+ excretion.
The blood buffer system can be activated within seconds
and the respiratory system can activate changes
in pH within minutes, whereas the third line of defense
is the renal system, which can take days to compensate
fully for the increase in CO2. These compensatory
changes result in increased oxygen transport to
tissues, increased chemoreceptor pO2 with a concomitant
decrease in CO2 and H+, increased vascular resistance
and decreased work capacity. This current findings
further support that pulmonary vascular capacity
of modern heavy weight broilers is marginally adequate
to accommodate the cardiac output required to sustain
the respiratory and metabolic demand for their rapid
growth.